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== References == <div id="h1-12-siblings" class="h1-siblings"></div> <div id="Abramowitz--2019"></div> Abramowitz, G. et al., 2019: ESD Reviews: Model dependence in multi-model climate ensembles: weighting, sub-selection and out-of-sample testing. ''Earth System Dynamics'' , '''10(1)''' , 91–105, doi: . <div id="Acosta Navarro--2016"></div> Acosta Navarro, J.C. et al., 2016: Amplification of Arctic warming by past air pollution reductions in Europe. ''Nature Geoscience'' , '''9(4)''' , 277–281, doi: . <div id="Acosta Navarro--2017"></div> Acosta Navarro, J.C. et al., 2017: Future Response of Temperature and Precipitation to Reduced Aerosol Emissions as Compared with Increased Greenhouse Gas Concentrations. ''Journal of Climate'' , '''30(3)''' , 939–954, doi: . <div id="Adams--2003"></div> Adams, J.B., M.E. Mann, and C.M. Ammann, 2003: Proxy evidence for an El Niño-like response to volcanic forcing. ''Nature'' , '''426(6964)''' , 274–278, doi: . <div id="Ahlm--2017"></div> Ahlm, L. et al., 2017: Marine cloud brightening – as effective without clouds. ''Atmospheric Chemistry and Physics'' , '''17(21)''' , 13071–13087, doi: . <div id="Akimoto--2018"></div> Akimoto, K., F. Sano, and T. Tomoda, 2018: GHG emission pathways until 2300 for the 1.5°C temperature rise target and the mitigation costs achieving the pathways. ''Mitigation and Adaptation Strategies for Global Change'' , '''23(6)''' , 839–852, doi: . <div id="Albern--2019"></div> Albern, N., A. Voigt, and J.G. Pinto, 2019: Cloud-Radiative Impact on the Regional Responses of the Midlatitude Jet Streams and Storm Tracks to Global Warming. ''Journal of Advances in Modeling Earth Systems'' , '''11(7)''' , 1940–1958, doi: . <div id="Alessandri--2014"></div> Alessandri, A. et al., 2014: Multi-scale enhancement of climate prediction over land by increasing the model sensitivity to vegetation variability in EC-Earth. ''Journal of Climate'' , '''49(4)''' , 8563–8577, doi: . <div id="Alexeev--2013"></div> Alexeev, V.A. and C.H. Jackson, 2013: Polar amplification: is atmospheric heat transport important? ''Climate Dynamics'' , '''41(2)''' , 533–547, doi: . <div id="Allen--2002"></div> Allen, M.R. and W.J. Ingram, 2002: Constraints on future changes in climate and the hydrologic cycle. ''Nature'' , '''419(6903)''' , 224–232, doi: . <div id="Allen--2018"></div> Allen, M.R. et al., 2018: Framing and Context. In: ''Global Warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the threat of climate change,'' ''sustainable development, and efforts to eradicate poverty'' [Masson-Delmotte, V., P. Zhai, H.-O. Pörtner, D. Roberts, J. Skea, P.R. Shukla, A. Pirani, W. Moufouma-Okia, C. Péan, R. Pidcock, S. Connors, J.B.R. Matthews, Y. Chen, X. Zhou, M.I. Gomis, E. Lonnoy, T. Maycock, M. Tignor, and T. Waterfield (eds.)]. In Press, pp. 49–92, . <div id="Allen--2020"></div> Allen, R.J. et al., 2020: Climate and air quality impacts due to mitigation of non-methane near-term climate forcers. ''Atmospheric Chemistry and Physics'' , '''20(16)''' , 9641–9663, doi: . <div id="Allen--2021"></div> Allen, R.J. et al., 2021: Significant climate benefits from near-term climate forcer mitigation in spite of aerosol reductions. ''Environmental Research Letters'' , '''16(3)''' , 034010, doi: . <div id="Alley--2003"></div> Alley, R.B. et al., 2003: Abrupt Climate Change. ''Science'' , '''299(5615)''' , 2005–2010, doi: . <div id="Alterskjær--2013"></div> Alterskjær, K. and J.E. Kristjánsson, 2013: The sign of the radiative forcing from marine cloud brightening depends on both particle size and injection amount. ''Geophysical Research Letters'' , '''40(1)''' , 210–215, doi: . <div id="Alterskjær--2013"></div> Alterskjær, K. et al., 2013: Sea-salt injections into the low-latitude marine boundary layer: The transient response in three Earth system models. ''Journal of Geophysical Research: Atmospheres'' , '''118(21)''' , 12195–12206, doi: . <div id="Amann--2013"></div> Amann, M., Z. Klimont, and F. Wagner, 2013: Regional and Global Emissions of Air Pollutants: Recent Trends and Future Scenarios. ''Annual Review of Environment and Resources'' , '''38(1)''' , 31–55, doi: . <div id="Andrews--2020"></div> Andrews, M.B. et al., 2020: Historical Simulations With HadGEM3-GC3.1 for CMIP6. ''Journal of Advances in Modeling Earth Systems'' , '''12(6)''' , e2019MS001995, doi: . <div id="Andrews--2010"></div> Andrews, T. and P.M. Forster, 2010: The transient response of global-mean precipitation to increasing carbon dioxide levels. ''Environmental Research Letters'' , '''5(2)''' , 1–6, doi: . <div id="Andrews--2009"></div> Andrews, T., P.M. Forster, and J.M. Gregory, 2009: A surface energy perspective on climate change. ''Journal of Climate'' , '''22(10)''' , 2557–2570, doi: . <div id="Andrews--2019"></div> Andrews, T. et al., 2019: Forcings, Feedbacks, and Climate Sensitivity in HadGEM3-GC3.1 and UKESM1. ''Journal of Advances in Modeling Earth Systems'' , '''11(12)''' , 4377–4394, doi: . <div id="Annan--2017"></div> Annan, J.D. and J.C. Hargreaves, 2017: On the meaning of independence in climate science. ''Earth System Dynamics'' , '''8''' , 211–224, doi: . <div id="Aquila--2014"></div> Aquila, V., C.I. Garfinkel, P.A. Newman, L.D. Oman, and D.W. Waugh, 2014: Modifications of the quasi-biennial oscillation by a geoengineering perturbation of the stratospheric aerosol layer. ''Geophysical Research Letters'' , '''41(5)''' , 1738–1744, doi: . <div id="Armour--2019"></div> Armour, K.C., N. Siler, A. Donohoe, and G.H. Roe, 2019: Meridional Atmospheric Heat Transport Constrained by Energetics and Mediated by Large-Scale Diffusion. ''Journal of Climate'' , '''32(12)''' , 3655–3680, doi: . <div id="Armour--2016"></div> Armour, K.C., J. Marshall, J.R. Scott, A. Donohoe, and E.R. Newsom, 2016: Southern Ocean warming delayed by circumpolar upwelling and equatorward transport. ''Nature Geoscience'' , '''9''' , 549–554, doi: . <div id="Arora--2020"></div> Arora, V.K. et al., 2020: Carbon–concentration and carbon–climate feedbacks in CMIP6 models and their comparison to CMIP5 models. ''Biogeosciences'' , '''17(16)''' , 4173–4222, doi: . <div id="Arrhenius--1896"></div> Arrhenius, S., 1896: On the influence of carbonic acid in the air upon the temperature of the ground. ''The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science'' , '''41(251)''' , 237–276, doi: . <div id="Årthun--2018"></div> Årthun, M., K.E. W., T. Eldevik, and K.N. S., 2018: Time Scales and Sources of European Temperature Variability. ''Geophysical Research Letters'' , '''45(8)''' , 3597–3604, doi: . <div id="Årthun--2017"></div> Årthun, M. et al., 2017: Skillful prediction of northern climate provided by the ocean. ''Nature Communications'' , '''8(1)''' , 15875, doi: . <div id="Athanasiadis--2020"></div> Athanasiadis, P.J. et al., 2020: Decadal predictability of North Atlantic blocking and the NAO. ''npj Climate and Atmospheric Science'' , '''3(1)''' , 20, doi: . <div id="Baker--2018"></div> Baker, L.H., L.C. Shaffrey, R.T. Sutton, A. Weisheimer, and A.A. Scaife, 2018: An Intercomparison of Skill and Overconfidence/Underconfidence of the Wintertime North Atlantic Oscillation in Multimodel Seasonal Forecasts. ''Geophysical Research Letters'' , '''45(15)''' , 7808–7817, doi: . <div id="Bala--2010"></div> Bala, G., K. Caldeira, and R. Nemani, 2010: Fast versus slow response in climate change: Implications for the global hydrological cycle. ''Climate Dynamics'' , '''35(2–3)''' , 423–434, doi: . <div id="Bala--2011"></div> Bala, G. et al., 2011: Albedo enhancement of marine clouds to counteract global warming: impacts on the hydrological cycle. ''Climate Dynamics'' , '''37(5)''' , 915–931, doi: . <div id="Balaji--2018"></div> Balaji, V. et al., 2018: Requirements for a global data infrastructure in support of CMIP6. ''Geoscientific Model Development'' , '''11(9)''' , 3659–3680, doi: . <div id="Ban--2015"></div> Ban, N., J. Schmidli, and C. Schär, 2015: Heavy precipitation in a changing climate: Does short-term summer precipitation increase faster? ''Geophysical Research Letters'' , '''42(4)''' , 1165–1172, doi: . <div id="Banerjee--2018"></div> Banerjee, A., A.C. Maycock, and J.A. Pyle, 2018: Chemical and climatic drivers of radiative forcing due to changes in stratospheric and tropospheric ozone over the 21st century. ''Atmospheric Chemistry and Physics'' , '''18(4)''' , 2899–2911, doi: . <div id="Banerjee--2020"></div> Banerjee, A., J.C. Fyfe, L.M. Polvani, D. Waugh, and K.-L. Chang, 2020: A pause in Southern Hemisphere circulation trends due to the Montreal Protocol. ''Nature'' , '''579(7800)''' , 544–548, doi: . <div id="Banerjee--2014"></div> Banerjee, A. et al., 2014: Lightning NO <sub>x</sub> , a key chemistry-climate interaction: Impacts of future climate change and consequences for tropospheric oxidising capacity. ''Atmospheric Chemistry and Physics'' , '''14(18)''' , 9871–9881, doi: . <div id="Barcikowska--2018"></div> Barcikowska, M.J. et al., 2018: Euro-Atlantic winter storminess and precipitation extremes under 1.5°C vs. 2°C warming scenarios. ''Earth System Dynamics'' , '''9(2)''' , 679–699, doi: . <div id="Barnes--2013"></div> Barnes, E.A. and L. Polvani, 2013: Response of the Midlatitude Jets, and of Their Variability, to Increased Greenhouse Gases in the CMIP5 Models. ''Journal of Climate'' , '''26(18)''' , 7117–7135, doi: . <div id="Barnes--2015"></div> Barnes, E.A. and L.M. Polvani, 2015: CMIP5 projections of arctic amplification, of the North American/North Atlantic circulation, and of their relationship. ''Journal of Climate'' , '''28''' , 5254–5271, doi: . <div id="Barnes--2014"></div> Barnes, E.A., N.W. Barnes, and L.M. Polvani, 2014: Delayed southern hemisphere climate change induced by stratospheric ozone recovery, as projected by the CMIP5 models. ''Journal of Climate'' , '''27''' , 852–867, doi: . <div id="Barriopedro--2010"></div> Barriopedro, D., R. García-Herrera, and R.M. Trigo, 2010: Application of blocking diagnosis methods to General Circulation Models. Part I: a novel detection scheme. ''Climate Dynamics'' , '''35(7–8)''' , 1373–1391, doi: . <div id="Bathiany--2020"></div> Bathiany, S., J. Hidding, and M. Scheffer, 2020: Edge Detection Reveals Abrupt and Extreme Climate Events. ''Journal of Climate'' , '''33(15)''' , 6399–6421, doi: . <div id="Bathiany--2018"></div> Bathiany, S., V. Dakos, M. Scheffer, and T.M. Lenton, 2018: Climate models predict increasing temperature variability in poor countries. ''Science Advances'' , '''4(5)''' , eaar5809, doi: . <div id="Bathiany--2016"></div> Bathiany, S., D. Notz, T. Mauritsen, G. Raedel, and V. Brovkin, 2016: On the potential for abrupt Arctic winter sea ice loss. ''Journal of Climate'' , '''29(7)''' , 2703–2719, doi: . <div id="Batté--2015"></div> Batté, L. and F.J. Doblas-Reyes, 2015: Stochastic atmospheric perturbations in the EC-Earth3 global coupled model: impact of SPPT on seasonal forecast quality. ''Climate Dynamics'' , '''45(11)''' , 3419–3439, doi: . <div id="Baumberger--2017"></div> Baumberger, C., R. Knutti, and G. Hirsch Hadorn, 2017: Building confidence in climate model projections: an analysis of inferences from fit. ''WIREs Climate Change'' , '''8(3)''' , e454, doi: . <div id="Bayr--2013"></div> Bayr, T. and D. Dommenget, 2013: The Tropospheric Land–Sea Warming Contrast as the Driver of Tropical Sea Level Pressure Changes. ''Journal of Climate'' , '''26(4)''' , 1387–1402, doi: . <div id="Beer--2020"></div> Beer, E., I. Eisenman, and T.J.W. Wagner, 2020: Polar Amplification Due to Enhanced Heat Flux Across the Halocline. ''Geophysical Research Letters'' , '''47(4)''' , e2019GL086706, doi: . <div id="Befort--2020"></div> Befort, D.J., C.H. O’Reilly, and A. Weisheimer, 2020: Constraining Projections Using Decadal Predictions. ''Geophysical Research Letters'' , '''47(18)''' , e2020GL087900, doi: . <div id="Bellomo--2018"></div> Bellomo, K., L.N. Murphy, M.A. Cane, A.C. Clement, and L.M. Polvani, 2018: Historical forcings as main drivers of the Atlantic multidecadal variability in the CESM large ensemble. ''Climate Dynamics'' , '''50(9)''' , 3687–3698, doi: . <div id="Bellucci--2017"></div> Bellucci, A., A. Mariotti, and S. Gualdi, 2017: The Role of Forcings in the Twentieth-Century North Atlantic Multidecadal Variability: The 1940–75 North Atlantic Cooling Case Study. ''Journal of Climate'' , '''30(18)''' , 7317–7337, doi: . <div id="Bellucci--2015a"></div> Bellucci, A. et al., 2015a: Advancements in decadal climate predictability: The role of nonoceanic drivers. ''Reviews of Geophysics'' , '''53(2)''' , 165–202, doi: . <div id="Bellucci--2015b"></div> Bellucci, A. et al., 2015b: An assessment of a multi-model ensemble of decadal climate predictions. ''Climate Dynamics'' , '''44(9–10)''' , 2787–2806, doi: . <div id="Bengtsson--2019"></div> Bengtsson, L. and K.I. Hodges, 2019: Can an ensemble climate simulation be used to separate climate change signals from internal unforced variability? ''Climate Dynamics'' , '''52(5–6)''' , 3553–3573, doi: . <div id="Berdahl--2014"></div> Berdahl, M. et al., 2014: Arctic cryosphere response in the Geoengineering Model Intercomparison Project G3 and G4 scenarios. ''Journal of Geophysical Research: Atmospheres'' , '''119(3)''' , 1308–1321, doi: . <div id="Berg--2016"></div> Berg, A. et al., 2016: Land–atmosphere feedbacks amplify aridity increase over land under global warming. ''Nature Climate Change'' , '''6(9)''' , 869–874, doi: . <div id="Berner--2017"></div> Berner, J. et al., 2017: Stochastic Parameterization: Toward a New View of Weather and Climate Models. ''Bulletin of the American Meteorological Society'' , '''98(3)''' , 565–588, doi: . <div id="Bethke--2017"></div> Bethke, I. et al., 2017: Potential volcanic impacts on future climate variability. ''Nature Climate Change'' , '''7(11)''' , 799–805, doi: . <div id="Bilbao--2021"></div> Bilbao, R. et al., 2021: Assessment of a full-field initialized decadal climate prediction system with the CMIP6 version of EC-Earth. ''Earth System Dynamics'' , '''12(1)''' , 173–196, doi: . <div id="Bindoff--2013"></div> Bindoff, N.L. et al., 2013: Detection and Attribution of Climate Change: from Global to Regional. In: ''Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change'' [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 867–952, doi: . <div id="Bitz--2006"></div> Bitz, C.M., P.R. Gent, R.A. Woodgate, M.M. Holland, and R. Lindsay, 2006: The influence of sea ice on ocean heat uptake in response to increasing CO <sub>2</sub> . ''Journal of Climate'' , '''19(11)''' , 2437–2450, doi: . <div id="Boé--2018"></div> Boé, J., 2018: Interdependency in Multimodel Climate Projections: Component Replication and Result Similarity. ''Geophysical Research Letters'' , '''45(6)''' , 2771–2779, doi: . <div id="Boer--2019"></div> Boer, G.J. and R. Sospedra-Alfonso, 2019: Assessing the skill of the Pacific Decadal Oscillation (PDO) in a decadal prediction experiment. ''Climate Dynamics'' , '''53(9)''' , 5763–5775, doi: . <div id="Boer--2013"></div> Boer, G.J., V. Kharin, and W.J. Merryfield, 2013: Decadal predictability and forecast skill. ''Climate Dynamics'' , '''41(7–8)''' , 1817–1833, doi: . <div id="Boer--2016"></div> Boer, G.J. et al., 2016: The Decadal Climate Prediction Project (DCPP) contribution to CMIP6. ''Geoscientific Model Development'' , '''9(10)''' , 3751–3777, doi: . <div id="Bollasina--2011"></div> Bollasina, M.A., Y. Ming, and V. Ramaswamy, 2011: Anthropogenic Aerosols and the Weakening of the South Asian Summer Monsoon. ''Science'' , '''334(6055)''' , 502–505, doi: . <div id="Bonan--2018"></div> Bonan, D.B., K.C. Armour, G.H. Roe, N. Siler, and N. Feldl, 2018: Sources of Uncertainty in the Meridional Pattern of Climate Change. ''Geophysical Research Letters'' , '''45''' , 9131–9140, doi: . <div id="Bony--2013"></div> Bony, S. et al., 2013: Robust direct effect of carbon dioxide on tropical circulation and regional precipitation. ''Nature Geoscience'' , '''6(6)''' , 447–451, doi: . <div id="Borchert--2019"></div> Borchert, L.F. et al., 2019: Decadal Predictions of the Probability of Occurrence for Warm Summer Temperature Extremes. ''Geophysical Research Letters'' , '''46(23)''' , 14042–14051, doi: . <div id="Borchert--2021"></div> Borchert, L.F. et al., 2021: Improved Decadal Predictions of North Atlantic Subpolar Gyre SST in CMIP6. ''Geophysical Research Letters'' , '''48(3)''' , e2020GL091307, doi: . <div id="Bordbar--2019"></div> Bordbar, M.H. et al., 2019: Uncertainty in near-term global surface warming linked to tropical Pacific climate variability. ''Nature Communications'' , '''10(1)''' , 1990, doi: . <div id="Borodina--2017"></div> Borodina, A., E.M. Fischer, and R. Knutti, 2017: Emergent constraints in climate projections: A case study of changes in high-latitude temperature variability. ''Journal of Climate'' , '''30''' , 3655–3670, doi: . <div id="Boucher--2017"></div> Boucher, O., C. Kleinschmitt, and G. Myhre, 2017: Quasi-Additivity of the Radiative Effects of Marine Cloud Brightening and Stratospheric Sulfate Aerosol Injection. ''Geophysical Research Letters'' , '''44(21)''' , 11158–11165, doi: . <div id="Boucher--2012"></div> Boucher, O. et al., 2012: Reversibility in an Earth System model in response to CO <sub>2</sub> concentration changes. ''Environmental Research Letters'' , '''7(2)''' , 024013, doi: . <div id="Boucher--2013"></div> Boucher, O. et al., 2013: Clouds and Aerosols. In: ''Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change'' [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 571–657, doi: . <div id="Bracegirdle--2018"></div> Bracegirdle, T.J., H. Lu, R. Eade, and T. Woollings, 2018: Do CMIP5 Models Reproduce Observed Low-Frequency North Atlantic Jet Variability? ''Geophysical Research Letters'' , '''45(14)''' , 7204–7212, doi: . <div id="Bracegirdle--2020a"></div> Bracegirdle, T.J. et al., 2020a: Improvements in Circumpolar Southern Hemisphere Extratropical Atmospheric Circulation in CMIP6 Compared to CMIP5. ''Earth and Space Science'' , '''7(6)''' , e2019EA001065, doi: . <div id="Bracegirdle--2020b"></div> Bracegirdle, T.J. et al., 2020b: Twenty first century changes in Antarctic and Southern Ocean surface climate in CMIP6. ''Atmospheric Science Letters'' , '''21(9)''' , e984, doi: . <div id="Bradley--2003"></div> Bradley, R.S., K.R. Briffa, J. Cole, M.K. Hughes, and T.J. Osborn, 2003: The Climate of the Last Millennium. In: ''Paleoclimate, Global Change and the Future'' [Alverson, K.D., T.F. Pedersen, and R.S. Bradley (eds.)]. Global Change – The IGBP Series, Springer, Berlin and Heidelberg, Germany, pp. 105–141, doi: . <div id="Branstator--2010"></div> Branstator, G. and H.Y. Teng, 2010: Two limits of initial-value decadal predictability in a CGCM. ''Journal of Climate'' , '''23(23)''' , 6292–6311, doi: . <div id="Brient--2020"></div> Brient, F., 2020: Reducing Uncertainties in Climate Projections with Emergent Constraints: Concepts, Examples and Prospects. ''Advances in Atmospheric Sciences'' , '''37(1)''' , 1–15, doi: . <div id="Bright--2017"></div> Bright, R.M. et al., 2017: Local temperature response to land cover and management change driven by non-radiative processes. ''Nature Climate Change'' , '''7(4)''' , 296–302, doi: . <div id="Brogli--2019"></div> Brogli, R., N. Kröner, S.L. Sørland, D. Lüthi, and C. Schär, 2019: The Role of Hadley Circulation and Lapse-Rate Changes for the Future European Summer Climate. ''Journal of Climate'' , '''32(2)''' , 385–404, doi: . <div id="Brönnimann--2019"></div> Brönnimann, S. et al., 2019: Last phase of the Little Ice Age forced by volcanic eruptions. ''Nature Geoscience'' , '''12(8)''' , 650–656, doi: . <div id="Bronselaer--2018"></div> Bronselaer, B. et al., 2018: Change in future climate due to Antarctic meltwater. ''Nature'' , '''564''' , 55–58, doi: . <div id="Brown--2020"></div> Brown, J.R. et al., 2020: Comparison of past and future simulations of ENSO in CMIP5/PMIP3 and CMIP6/PMIP4 models. ''Climate of the Past'' , '''16(5)''' , 1777–1805, doi: . <div id="Brown--2016"></div> Brown, P.T., M.S. Lozier, R. Zhang, and W. Li, 2016: The necessity of cloud feedback for a basin-scale Atlantic Multidecadal Oscillation. ''Geophysical Research Letters'' , '''43(8)''' , 3955–3963, doi: . <div id="Brown--2017"></div> Brown, P.T., Y. Ming, W. Li, and S.A. Hill, 2017: Change in the magnitude and mechanisms of global temperature variability with warming. ''Nature Climate Change'' , '''7(10)''' , 743–748, doi: . <div id="Brune--2020"></div> Brune, S. and J. Baehr, 2020: Preserving the coupled atmosphere–ocean feedback in initializations of decadal climate predictions. ''WIREs Climate Change'' , '''11(3)''' , e637, doi: . <div id="Brune--2018"></div> Brune, S., A. Düsterhus, H. Pohlmann, W.A. Müller, and J. Baehr, 2018: Time dependency of the prediction skill for the North Atlantic subpolar gyre in initialized decadal hindcasts. ''Climate Dynamics'' , '''51(5)''' , 1947–1970, doi: . <div id="Brunner--2020"></div> Brunner, L. et al., 2020: Reduced global warming from CMIP6 projections when weighting models by performance and independence. ''Earth System Dynamics'' , '''11(4)''' , 995–1012, doi: . <div id="Buntgen--2016"></div> Büntgen, U. et al., 2016: Cooling and societal change during the Late Antique Little Ice Age from 536 to around 660 AD. ''Nature Geoscience'' , '''9(3)''' , 231–236, doi: . <div id="Burger--2015"></div> Bürger, G. and U. Cubasch, 2015: The detectability of climate engineering. ''Journal of Geophysical Research: Atmospheres'' , '''120(22)''' , 11404–11418, doi: . <div id="Burke--2017"></div> Burke, E.J. et al., 2017: Quantifying uncertainties of permafrost carbon–climate feedbacks. ''Biogeosciences'' , '''14(12)''' , 3051–3066, doi: . <div id="Byrne--2013a"></div> Byrne, M.P. and P.A. O’Gorman, 2013a: Land–Ocean Warming Contrast over a Wide Range of Climates: Convective Quasi-Equilibrium Theory and Idealized Simulations. ''Journal of Climate'' , '''26(12)''' , 4000–4016, doi: . <div id="Byrne--2013b"></div> Byrne, M.P. and P.A. O’Gorman, 2013b: Link between land–ocean warming contrast and surface relative humidities in simulations with coupled climate models. ''Geophysical Research Letters'' , '''40''' , 5223–5227, doi: . <div id="Byrne--2015"></div> Byrne, M.P. and P.A. O’Gorman, 2015: The Response of Precipitation Minus Evapotranspiration to Climate Warming: Why the “Wet-Get-Wetter, Dry-Get-Drier” Scaling Does Not Hold over Land. ''Journal of Climate'' , '''28(20)''' , 8078–8092, doi: . <div id="Byrne--2016"></div> Byrne, M.P. and P.A. O’Gorman, 2016: Understanding Decreases in Land Relative Humidity with Global Warming: Conceptual Model and GCM Simulations. ''Journal of Climate'' , '''29(24)''' , 9045–9061, doi: . <div id="Byrne--2018"></div> Byrne, M.P. and P.A. O’Gorman, 2018: Trends in continental temperature and humidity directly linked to ocean warming. ''Proceedings of the National Academy of Sciences'' , '''115(19)''' , 4863–4868, doi: . <div id="Byrne--2019"></div> Byrne, N.J., T.G. Shepherd, and I. Polichtchouk, 2019: Subseasonal-to-Seasonal Predictability of the Southern Hemisphere Eddy-Driven Jet During Austral Spring and Early Summer. ''Journal of Geophysical Research: Atmospheres'' , '''124(13)''' , 6841–6855, doi: . <div id="Caesar--2013"></div> Caesar, J. et al., 2013: Response of the HadGEM2 Earth System Model to future greenhouse gas emissions pathways to the year 2300. ''Journal of Climate'' , '''26(10)''' , 3275–3284, doi: . <div id="Cai--2017"></div> Cai, W., G. Wang, A. Santoso, X. Lin, and L. Wu, 2017: Definition of Extreme El Niño and Its Impact on Projected Increase in Extreme El Niño Frequency. ''Geophysical Research Letters'' , '''44(21)''' , 11184-11190, doi: . <div id="Cai--2013"></div> Cai, W. et al., 2013: Projected response of the Indian Ocean Dipole to greenhouse warming. ''Nature Geoscience'' , '''6''' , 997–1007, doi: . <div id="Cai--2014a"></div> Cai, W. et al., 2014a: Increasing frequency of extreme El Niño events due to greenhouse warming. ''Nature Climate Change'' , '''4(2)''' , 111–116, doi: . <div id="Cai--2014b"></div> Cai, W. et al., 2014b: Increased frequency of extreme Indian Ocean Dipole events due to greenhouse warming. ''Nature'' , '''510''' , 254–258, doi: . <div id="Cai--2015"></div> Cai, W. et al., 2015: ENSO and greenhouse warming. ''Nature Climate Change'' , '''5(9)''' , 849–859, doi: . <div id="Cai--2018a"></div> Cai, W. et al., 2018a: Increased variability of eastern Pacific El Niño under greenhouse warming. ''Nature'' , '''564(7735)''' , 201–206, doi: . <div id="Cai--2018b"></div> Cai, W. et al., 2018b: Stabilised frequency of extreme positive Indian Ocean Dipole under 1.5°C warming. ''Nature Communications'' , '''9(1)''' , 1419, doi: . <div id="Cai--2019"></div> Cai, W. et al., 2019: Pantropical climate interactions. ''Science'' , '''363(6430)''' , eaav4236, doi: . <div id="Cai--2021"></div> Cai, W. et al., 2021: Opposite response of strong and moderate positive Indian Ocean Dipole to global warming. ''Nature Climate Change'' , '''11(1)''' , 27–32, doi: . <div id="Caian--2018"></div> Caian, M., T. Koenigk, R. Döscher, and A. Devasthale, 2018: An interannual link between Arctic sea-ice cover and the North Atlantic Oscillation. ''Climate Dynamics'' , '''50(1–2)''' , 423–441, doi: . <div id="Cao--2011"></div> Cao, L., G. Bala, and K. Caldeira, 2011: Why is there a short-term increase in global precipitation in response to diminished CO <sub>2</sub> forcing? ''Geophysical Research Letters'' , '''38(6)''' , L06703, doi: . <div id="Cao--2015"></div> Cao, L., G. Bala, M. Zheng, and K. Caldeira, 2015: Fast and slow climate responses to CO <sub>2</sub> and solar forcing: A linear multivariate regression model characterizing transient climate change. ''Journal of Geophysical Research: Atmospheres'' , '''120(23)''' , 12037–12053, doi: . <div id="Cao--2016"></div> Cao, L., L. Duan, G. Bala, and K. Caldeira, 2016: Simulated long-term climate response to idealized solar geoengineering. ''Geophysical Research Letters'' , '''43(5)''' , 2209–2217, doi: . <div id="Cao--2017"></div> Cao, L., L. Duan, G. Bala, and K. Caldeira, 2017: Simultaneous stabilization of global temperature and precipitation through cocktail geoengineering. ''Geophysical Research Letters'' , '''44(14)''' , 7429–7437, doi: . <div id="Caron--2017"></div> Caron, L.-P. et al., 2017: How Skillful are the Multiannual Forecasts of Atlantic Hurricane Activity? ''Bulletin of the American Meteorological Society'' , '''99(2)''' , 403–413, doi: . <div id="Cassou--2016"></div> Cassou, C. and J. Cattiaux, 2016: Disruption of the European climate seasonal clock in a warming world. ''Nature Climate Change'' , '''6(6)''' , 589–594, doi: . <div id="Cassou--2018"></div> Cassou, C. et al., 2018: Decadal Climate Variability and Predictability: Challenges and Opportunities. ''Bulletin of the American Meteorological Society'' , '''99(3)''' , 479–490, doi: . <div id="Ceppi--2016"></div> Ceppi, P. and D.L. Hartmann, 2016: Clouds and the Atmospheric Circulation Response to Warming. ''Journal of Climate'' , '''29(2)''' , 783–799, doi: . <div id="Ceppi--2017"></div> Ceppi, P. and T.G. Shepherd, 2017: Contributions of Climate Feedbacks to Changes in Atmospheric Circulation. ''Journal of Climate'' , '''30(22)''' , 9097–9118, doi: . <div id="Ceppi--2019"></div> Ceppi, P. and T.G. [[#Shepherd--2019|Shepherd, 2019]] : The Role of the Stratospheric Polar Vortex for the Austral Jet Response to Greenhouse Gas Forcing. ''Geophysical Research Letters'' , '''46(12)''' , 6972–6979, doi: . <div id="Ceppi--2014"></div> Ceppi, P., M.D. Zelinka, and D.L. Hartmann, 2014: The response of the Southern Hemispheric eddy-driven jet to future changes in shortwave radiation in CMIP5. ''Geophysical Research Letters'' , '''41(9)''' , 3244–3250, doi: . <div id="Ceppi--2018"></div> Ceppi, P., G. Zappa, T.G. Shepherd, and J.M. Gregory, 2018: Fast and Slow Components of the Extratropical Atmospheric Circulation Response to CO <sub>2</sub> forcing. ''Journal of Climate'' , '''31(3)''' , 1091–1105, doi: . <div id="Chadwick--2016"></div> Chadwick, R., 2016: Which Aspects of CO <sub>2</sub> forcing and SST Warming Cause Most Uncertainty in Projections of Tropical Rainfall Change over Land and Ocean? ''Journal of Climate'' , '''29(7)''' , 2493–2509, doi: . <div id="Chadwick--2013"></div> Chadwick, R., I. Boutle, and G. Martin, 2013: Spatial Patterns of Precipitation Change in CMIP5: Why the Rich Do Not Get Richer in the Tropics. ''Journal of Climate'' , '''26(11)''' , 3803–3822, doi: . <div id="Chadwick--2016"></div> Chadwick, R., P. Good, and K. Willett, 2016: A Simple Moisture Advection Model of Specific Humidity Change over Land in Response to SST Warming. ''Journal of Climate'' , '''29(21)''' , 7613–7632, doi: . <div id="Chadwick--2017"></div> Chadwick, R., H. Douville, and C.B. Skinner, 2017: Timeslice experiments for understanding regional climate projections: applications to the tropical hydrological cycle and European winter circulation. ''Climate Dynamics'' , '''49(9–10)''' , 3011–3029, doi: . <div id="Chalmers--2012"></div> Chalmers, N., E.J. Highwood, E. Hawkins, R. Sutton, and L.J. Wilcox, 2012: Aerosol contribution to the rapid warming of near-term climate under RCP 2.6. ''Geophysical Research Letters'' , '''39(17)''' , 2–7, doi: . <div id="Chand--2017"></div> Chand, S.S., K.J. Tory, H. Ye, and K.J.E. Walsh, 2017: Projected increase in El Niño-driven tropical cyclone frequency in the Pacific. ''Nature Climate Change'' , '''7''' , 123–127, doi: . <div id="Chang--2017"></div> Chang, E.K.-M., 2017: Projected Significant Increase in the Number of Extreme Extratropical Cyclones in the Southern Hemisphere. ''Journal of Climate'' , '''30(13)''' , 4915–4935, doi: . <div id="Chang--2018"></div> Chang, E.K.-M., 2018: CMIP5 Projected Change in Northern Hemisphere Winter Cyclones with Associated Extreme Winds. ''Journal of Climate'' , '''31(16)''' , 6527–6542, doi: . <div id="Chang--2016"></div> Chang, E.K.-M., C.-G. Ma, C. Zheng, and A.M.W. Yau, 2016: Observed and projected decrease in Northern Hemisphere extratropical cyclone activity in summer and its impacts on maximum temperature. ''Geophysical Research Letters'' , '''43(5)''' , 2200–2208, doi: . <div id="Chavaillaz--2016"></div> Chavaillaz, Y., S. Joussaume, S. Bony, and P. Braconnot, 2016: Spatial stabilization and intensification of moistening and drying rate patterns under future climate change. ''Climate Dynamics'' , '''47(3–4)''' , 951–965, doi: . <div id="Chen--2019"></div> Chen, G. et al., 2019: Thermodynamic and Dynamic Mechanisms for Hydrological Cycle Intensification over the Full Probability Distribution of Precipitation Events. ''Journal of the Atmospheric Sciences'' , '''76(2)''' , 497–516, doi: . <div id="Chen--2017"></div> Chen, L., T. Li, Y. Yu, and S.K. Behera, 2017: A possible explanation for the divergent projection of ENSO amplitude change under global warming. ''Climate Dynamics'' , '''49(11–12)''' , 3799–3811, doi: . <div id="Chen--2012"></div> Chen, Y.-C. et al., 2012: Occurrence of lower cloud albedo in ship tracks. ''Atmospheric Chemistry and Physics'' , '''12(17)''' , 8223–8235, doi: . <div id="Chen--2020"></div> Chen, Z. et al., 2020: Global Land Monsoon Precipitation Changes in CMIP6 Projections. ''Geophysical Research Letters'' , '''47(14)''' , e2019GL086902, doi: . <div id="Cheng--2019"></div> Cheng, W. et al., 2019: Soil Moisture and Other Hydrological Changes in a Stratospheric Aerosol Geoengineering Large Ensemble. ''Journal of Geophysical Research: Atmospheres'' , '''124(23)''' , 12773–12793, doi: . <div id="Chevuturi--2018"></div> Chevuturi, A., N.P. Klingaman, A.G. Turner, and S. Hannah, 2018: Projected Changes in the Asian-Australian Monsoon Region in 1.5°C and 2.0°C Global-Warming Scenarios. ''Earth’s Future'' , '''6(3)''' , 339–358, doi: . <div id="Chikamoto--2017"></div> Chikamoto, Y., A. Timmermann, M.J. Widlansky, M.A. Balmaseda, and L. Stott, 2017: Multi-year predictability of climate, drought, and wildfire in southwestern North America. ''Scientific Reports'' , '''7(1)''' , 6568, doi: . <div id="Chikamoto--2019"></div> Chikamoto, Y., A. Timmermann, M.J. Widlansky, S. Zhang, and M.A. Balmaseda, 2019: A Drift-Free Decadal Climate Prediction System for the Community Earth System Model. ''Journal of Climate'' , '''32(18)''' , 5967–5995, doi: . <div id="Chikamoto--2013"></div> Chikamoto, Y. et al., 2013: An overview of decadal climate predictability in a multi-model ensemble by climate model MIROC. ''Climate Dynamics'' , '''40''' '''(5–6''' ''')''' , 1201–1222, doi: . <div id="Chikamoto--2015"></div> Chikamoto, Y. et al., 2015: Skilful multi-year predictions of tropical trans-basin climate variability. ''Nature Communications'' , '''6(1)''' , 6869, doi: . <div id="Chiodo--2016"></div> Chiodo, G. and L.M. Polvani, 2016: Reduction of Climate Sensitivity to Solar Forcing due to Stratospheric Ozone Feedback. ''Journal of Climate'' , '''29(12)''' , 4651–4663, doi: . <div id="Chiodo--2019"></div> Chiodo, G., J. Oehrlein, L.M. Polvani, J.C. Fyfe, and A.K. Smith, 2019: Insignificant influence of the 11-year solar cycle on the North Atlantic Oscillation. ''Nature Geoscience'' , '''12(2)''' , 94–99, doi: . <div id="Choi--2019"></div> Choi, J., S.W. Son, and R.J. Park, 2019: Aerosol versus greenhouse gas impacts on Southern Hemisphere general circulation changes. ''Climate Dynamics'' , '''52(7–8)''' , 4127–4142, doi: . <div id="Chou--2009"></div> Chou, C., J.D. Neelin, C.-A. Chen, and J.-Y. Tu, 2009: Evaluating the “Rich-Get-Richer” Mechanism in Tropical Precipitation Change under Global Warming. ''Journal of Climate'' , '''22(8)''' , 1982–2005, doi: . <div id="Christensen--2019"></div> Christensen, H.M. and J. Berner, 2019: From reliable weather forecasts to skilful climate response: A dynamical systems approach. ''Quarterly Journal of the Royal Meteorological Society'' , '''145(720)''' , 1052–1069, doi: . <div id="Christensen--2017"></div> Christensen, H.M., J. Berner, D.R.B. Coleman, and T.N. Palmer, 2017: Stochastic Parameterization and El Niño-Southern Oscillation. ''Journal of Climate'' , '''30''' , 17–38, doi: . <div id="Christensen--2013"></div> Christensen, J.H. et al., 2013: Climate Phenomena and their Relevance for Future Regional Climate Change. In: ''Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change'' [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 1217–1308, doi: . <div id="Christensen--2011"></div> Christensen, M.W. and G.L. Stephens, 2011: Microphysical and macrophysical responses of marine stratocumulus polluted by underlying ships: Evidence of cloud deepening. ''Journal of Geophysical Research: Atmospheres'' , '''116(D3)''' , D03201, doi: . <div id="Christensen--2018"></div> Christensen, P., K. Gillingham, and W. Nordhaus, 2018: Uncertainty in forecasts of long-run economic growth. ''Proceedings of the National Academy of Sciences'' , '''115(21)''' , 5409–5414, doi: . <div id="Chu--2014"></div> Chu, J.-E. et al., 2014: Future change of the Indian Ocean basin-wide and dipole modes in the CMIP5. ''Climate Dynamics'' , '''43(1–2)''' , 535–551, doi: . <div id="Chung--2019"></div> Chung, C.T.Y., S.B. Power, A. Sullivan, and F. Delage, 2019: The role of the South Pacific in modulating Tropical Pacific variability. ''Scientific Reports'' , '''9(1)''' , 18311, doi: . <div id="Church--2013"></div> Church, J. et al., 2013: Sea Level Change. In: ''Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change'' [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 1137–1216, doi: . <div id="Chuwah--2013"></div> Chuwah, C. et al., 2013: Implications of alternative assumptions regarding future air pollution control in scenarios similar to the Representative Concentration Pathways. ''Atmospheric Environment'' , '''79''' , 787–801, doi: . <div id="Chylek--2011"></div> Chylek, P., C.K. Folland, H.A. Dijkstra, G. Lesins, and M.K. Dubey, 2011: Ice-core data evidence for a prominent near 20 year time-scale of the Atlantic Multidecadal Oscillation. ''Geophysical Research Letters'' , '''38(13)''' , L13704, doi: . <div id="Ciais--2013"></div> Ciais, P. et al., 2013: Carbon and Other Biogeochemical Cycles. In: ''Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change'' [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 465–570, doi: . <div id="Ciavarella--2017"></div> Ciavarella, A., P. Stott, and J. Lowe, 2017: Early benefits of mitigation in risk of regional climate extremes. ''Nature Climate Change'' , '''7(5)''' , 326–330, doi: . <div id="Clark--2016"></div> Clark, P.U. et al., 2016: Consequences of twenty-first-century policy for multi-millennial climate and sea-level change. ''Nature Climate Change'' , '''6''' , 360–369, doi: . <div id="Claussen--2002"></div> Claussen, M. et al., 2002: Earth system models of intermediate complexity: closing the gap in the spectrum of climate system models. ''Climate Dynamics'' , '''18(7)''' , 579–586, doi: . <div id="Collins--2013"></div> Collins, M. et al., 2013: Long-term Climate Change: Projections, Commitments and Irreversibility. In: ''Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change'' [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 1029–1136, doi: . <div id="Collins--2018"></div> Collins, W.D., D.R. Feldman, C. Kuo, and N.H. Nguyen, 2018: Large regional shortwave forcing by anthropogenic methane informed by Jovian observations. ''Science Advances'' , '''4(9)''' , 1–10, doi: . <div id="Collins--2017"></div> Collins, W.J. et al., 2017: AerChemMIP: quantifying the effects of chemistry and aerosols in CMIP6. ''Geoscientific Model Development'' , '''10(2)''' , 585–607, doi: . <div id="Colose--2016"></div> Colose, C.M., A.N. LeGrande, and M. Vuille, 2016: The influence of volcanic eruptions on the climate of tropical South America during the last millennium in an isotope-enabled general circulation model. ''Climate of the Past'' , '''12(4)''' , 961–979, doi: . <div id="Connolly--2014"></div> Connolly, P.J., G.B. McFiggans, R. Wood, and A. Tsiamis, 2014: Factors determining the most efficient spray distribution for marine cloud brightening. ''Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences'' , '''372(2031)''' , 20140056, doi: . <div id="Corti--2012"></div> Corti, S., A. Weisheimer, T.N. Palmer, F.J. Doblas-Reyes, and L. Magnusson, 2012: Reliability of decadal predictions. ''Geophysical Research Letters'' , '''39''' , L21712, doi: . <div id="Corti--2015"></div> Corti, S. et al., 2015: Impact of initial conditions versus external forcing in decadal climate predictions: A sensitivity experiment. ''Journal of Climate'' , '''28''' , 4454–4470, doi: . <div id="Counillon--2014"></div> Counillon, F. et al., 2014: Seasonal-to-decadal predictions with the ensemble Kalman filter and the Norwegian Earth System Model: a twin experiment. ''Tellus A: Dynamic Meteorology and Oceanography'' , '''66(1)''' , 21074, doi: . <div id="Counillon--2016"></div> Counillon, F. et al., 2016: Flow-dependent assimilation of sea surface temperature in isopycnal coordinates with the Norwegian Climate Prediction Model. ''Tellus A: Dynamic Meteorology and Oceanography'' , '''68(1)''' , 32437, doi: . <div id="Cox--2007"></div> Cox, P.M. and D. Stephenson, 2007: A Changing Climate for Prediction. ''Science'' , '''317(5835)''' , 207–208, doi: . <div id="Cox--2018"></div> Cox, P.M., C. Huntingford, and M.S. Williamson, 2018: Emergent constraint on equilibrium climate sensitivity from global temperature variability. ''Nature'' , '''553(7688)''' , 319–322, doi: . <div id="Crook--2011"></div> Crook, J.A., P.M. Forster, and N. Stuber, 2011: Spatial patterns of modeled climate feedback and contributions to temperature response and polar amplification. ''Journal of Climate'' , '''24''' , 3575–3592, doi: . <div id="Crook--2015"></div> Crook, J.A., L.S. Jackson, S.M. Osprey, and P.M. Forster, 2015: A comparison of temperature and precipitation responses to different Earth radiation management geoengineering schemes. ''Journal of Geophysical Research: Atmospheres'' , '''120(18)''' , 9352–9373, doi: . <div id="Cubasch--2013"></div> Cubasch, U. et al., 2013: Introduction. In: ''Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change'' [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 119–158, doi: . <div id="Curry--2014"></div> Curry, C.L. et al., 2014: A multimodel examination of climate extremes in an idealized geoengineering experiment. ''Journal of Geophysical Research: Atmospheres'' , '''119(7)''' , 3900–3923, doi: . <div id="Curtis--2020"></div> Curtis, P.E., P. Ceppi, and G. Zappa, 2020: Role of the mean state for the Southern Hemispheric jet stream response to CO <sub>2</sub> forcing in CMIP6 models. ''Environmental Research Letters'' , '''15(6)''' , 064011, doi: . <div id="Dai--2019"></div> Dai, A. and C.E. Bloecker, 2019: Impacts of internal variability on temperature and precipitation trends in large ensemble simulations by two climate models. ''Climate Dynamics'' , '''52(1–2)''' , 289–306, doi: . <div id="Dai--2020"></div> Dai, P. et al., 2020: Seasonal to decadal predictions of regional Arctic sea ice by assimilating sea surface temperature in the Norwegian Climate Prediction Model. ''Climate Dynamics'' , '''54(9–10)''' , 3863–3878, doi: . <div id="Dai--2018"></div> Dai, Z., D.K. Weisenstein, and D.W. Keith, 2018: Tailoring Meridional and Seasonal Radiative Forcing by Sulfate Aerosol Solar Geoengineering. ''Geophysical Research Letters'' , '''45(2)''' , 1030–1039, doi: . <div id="Dakos--2008"></div> Dakos, V. et al., 2008: Slowing down as an early warning signal for abrupt climate change. ''Proceedings of the National Academy of Sciences'' , '''105(38)''' , 14308–14312, doi: . <div id="Danabasoglu--2009"></div> Danabasoglu, G. and P.R. Gent, 2009: Equilibrium climate sensitivity: Is it accurate to use a slab ocean model? ''Journal of Climate'' , '''22''' , 2494–2499, doi: . <div id="Davin--2014"></div> Davin, E.L., S.I. Seneviratne, P. Ciais, A. Olioso, and T. Wang, 2014: Preferential cooling of hot extremes from cropland albedo management. ''Proceedings of the National Academy of Sciences'' , '''111(27)''' , 9757–9761, doi: . <div id="Davini--2020"></div> Davini, P. and F. D’Andrea, 2020: From CMIP3 to CMIP6: Northern Hemisphere Atmospheric Blocking Simulation in Present and Future Climate. ''Journal of Climate'' , '''33(23)''' , 10021–10038, doi: . <div id="Davini--2012"></div> Davini, P., C. Cagnazzo, S. Gualdi, and A. Navarra, 2012: Bidimensional Diagnostics, Variability, and Trends of Northern Hemisphere Blocking. ''Journal of Climate'' , '''25(19)''' , 6496–6509, doi: . <div id="Davini--2017"></div> Davini, P. et al., 2017: Climate SPHINX: Evaluating the impact of resolution and stochastic physics parameterisations in the EC-Earth global climate model. ''Geoscientific Model Development'' , '''10''' , 1383–1402, doi: . <div id="Davis--2014"></div> Davis, S.J. and R.H. Socolow, 2014: Commitment accounting of CO <sub>2</sub> emissions. ''Environmental Research Letters'' , '''9(8)''' , 84018, doi: . <div id="Dawson--2015"></div> Dawson, A. and T.N. Palmer, 2015: Simulating weather regimes: impact of model resolution and stochastic parameterization. ''Climate Dynamics'' , '''44(7–8)''' , 2177–2193, doi: . <div id="de Coninck--2018"></div> de Coninck, H. et al., 2018: Strengthening and Implementing the Global Response Supplementary Material. In: ''Global Warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the threat of climate change,'' ''sustainable development, and efforts to eradicate poverty'' [Masson-Delmotte, V., P. Zhai, H.-O. Pörtner, D. Roberts, J. Skea, P.R. Shukla, A. Pirani, W. Moufouma-Okia, C. Péan, R. Pidcock, S. Connors, J.B.R. Matthews, Y. Chen, X. Zhou, M.I. Gomis, E. Lonnoy, T. Maycock, M. Tignor, and T. Waterfield (eds.)]. In Press, pp. 4SM: 1–82, . <div id="De Vries--2012"></div> De Vries, H., R.J. Haarsma, and W. Hazeleger, 2012: Western European cold spells in current and future climate. ''Geophysical Research Letters'' , '''39''' , L04706, doi: . <div id="Desch--2017"></div> Desch, S.J. et al., 2017: Arctic ice management. ''Earth’s Future'' , '''5(1)''' , 107–127, doi: . <div id="Deser--2015"></div> Deser, C., R.A. Tomas, and L. Sun, 2015: The Role of Ocean–Atmosphere Coupling in the Zonal-Mean Atmospheric Response to Arctic Sea Ice Loss. ''Journal of Climate'' , '''28(6)''' , 2168–2186, doi: . <div id="Deser--2016"></div> Deser, C., L. Terray, and A.S. Phillips, 2016: Forced and internal components of winter air temperature trends over North America during the past 50 years: Mechanisms and implications. ''Journal of Climate'' , '''29''' , 2237–2258, doi: . <div id="Deser--2017"></div> Deser, C., J.W. Hurrell, and A.S. Phillips, 2017: The role of the North Atlantic Oscillation in European climate projections. ''Climate Dynamics'' , '''49(9–10)''' , 3141–3157, doi: . <div id="Deser--2012a"></div> Deser, C., R. Knutti, S. Solomon, and A.S. Phillips, 2012a: Communication of the role of natural variability in future North American climate. ''Nature Climate Change'' , '''2(11)''' , 775–779, doi: . <div id="Deser--2012b"></div> Deser, C., A. Phillips, V. Bourdette, and H. Teng, 2012b: Uncertainty in climate change projections: the role of internal variability. ''Climate Dynamics'' , '''38(3)''' , 527–546, doi: . <div id="Deser--2014"></div> Deser, C., A.S. Phillips, M.A. Alexander, and B. Smoliak, 2014: Projecting North American climate over the next 50 years: Uncertainty due to internal variability. ''Journal of Climate'' , '''27(6)''' , 2271–2296, doi: . <div id="Deser--2020"></div> Deser, C. et al., 2020: Insights from Earth system model initial-condition large ensembles and future prospects. ''Nature Climate Change'' , '''10(4)''' , 277–286, doi: . <div id="Dhomse--2018"></div> Dhomse, S.S. et al., 2018: Estimates of ozone return dates from Chemistry-Climate Model Initiative simulations. ''Atmospheric Chemistry and Physics'' , '''18(11)''' , 8409–8438, doi: . <div id="Diamond--2020"></div> Diamond, M.S., H.M. Director, R. Eastman, A. Possner, and R. Wood, 2020: Substantial Cloud Brightening From Shipping in Subtropical Low Clouds. ''AGU Advances'' , '''1(1)''' , e2019AV000111, doi: . <div id="DiNezio--2020"></div> DiNezio, P.N., M. Puy, K. Thirumalai, F.-F. Jin, and J.E. Tierney, 2020: Emergence of an equatorial mode of climate variability in the Indian Ocean. ''Science Advances'' , '''6(19)''' , doi: . <div id="Doblas-Reyes--2013"></div> Doblas-Reyes, F.J. et al., 2013: Initialized near-term regional climate change prediction. ''Nature Communications'' , '''4''' , 1715, doi: . <div id="Dong--2009"></div> Dong, B., J.M. Gregory, and R.T. Sutton, 2009: Understanding Land–Sea Warming Contrast in Response to Increasing Greenhouse Gases. Part I: Transient Adjustment. ''Journal of Climate'' , '''22(11)''' , 3079–3097, doi: . <div id="Donohoe--2013"></div> Donohoe, A. and D.S. Battisti, 2013: The Seasonal Cycle of Atmospheric Heating and Temperature. ''Journal of Climate'' , '''26(14)''' , 4962–4980, doi: . <div id="Dosio--2018"></div> Dosio, A. and E.M. Fischer, 2018: Will Half a Degree Make a Difference? Robust Projections of Indices of Mean and Extreme Climate in Europe Under 1.5°C, 2°C, and 3°C Global Warming. ''Geophysical Research Letters'' , '''45(2)''' , 935–944, doi: . <div id="Dosio--2018"></div> Dosio, A., L. Mentaschi, E.M. Fischer, and K. Wyser, 2018: Extreme heat waves under 1.5°C and 2°C global warming. ''Environmental Research Letters'' , '''13(5)''' , 054006, doi: . <div id="Drijfhout--2015"></div> Drijfhout, S. et al., 2015: Catalogue of abrupt shifts in Intergovernmental Panel on Climate Change climate models. ''Proceedings of the National Academy of Sciences'' , '''112(43)''' , E5777–E5786, doi: . <div id="Drost--2012"></div> Drost, F., D. Karoly, and K. Braganza, 2012: Communicating global climate change using simple indices: an update. ''Climate Dynamics'' , '''39(3–4)''' , 989–999, doi: . <div id="Du--2013"></div> Du, Y. et al., 2013: Indian Ocean Variability in the CMIP5 Multimodel Ensemble: The Basin Mode. ''Journal of Climate'' , '''26(18)''' , 7240–7266, doi: . <div id="Duan--2018"></div> Duan, L., L. Cao, G. Bala, and K. Caldeira, 2018: Comparison of the Fast and Slow Climate Response to Three Radiation Management Geoengineering Schemes. ''Journal of Geophysical Research: Atmospheres'' , '''123(21)''' , 11980–12001, doi: . <div id="Duan--2019"></div> Duan, L., L. Cao, G. Bala, and K. Caldeira, 2019: Climate Response to Pulse Versus Sustained Stratospheric Aerosol Forcing. ''Geophysical Research Letters'' , '''46(15)''' , 8976–8984, doi: . <div id="Dunn-Sigouin--2013"></div> Dunn-Sigouin, E., S.-W. Son, and H. Lin, 2013: Evaluation of Northern Hemisphere Blocking Climatology in the Global Environment Multiscale Model. ''Monthly Weather Review'' , '''141(2)''' , 707–727, doi: . <div id="Dunstone--2011"></div> Dunstone, N.J., D.M. Smith, and R. Eade, 2011: Multi-year predictability of the tropical Atlantic atmosphere driven by the high latitude North Atlantic Ocean. ''Geophysical Research Letters'' , '''38(14)''' , L14701, doi: . <div id="Dunstone--2016"></div> Dunstone, N.J. et al., 2016: Skilful predictions of the winter North Atlantic Oscillation one year ahead. ''Nature Geoscience'' , '''9(11)''' , 809–814, doi: . <div id="Dwyer--2012"></div> Dwyer, J.G., M. Biasutti, and A.H. Sobel, 2012: Projected Changes in the Seasonal Cycle of Surface Temperature. ''Journal of Climate'' , '''25(18)''' , 6359–6374, doi: . <div id="Eade--2014"></div> Eade, R. et al., 2014: Do seasonal-to-decadal climate predictions underestimate the predictability of the real world? ''Geophysical Research Letters'' , '''41(15)''' , 5620–5628, doi: . <div id="Eby--2013"></div> Eby, M. et al., 2013: Historical and idealized climate model experiments: an intercomparison of Earth system models of intermediate complexity. ''Climate of the Past'' , '''9(3)''' , 1111–1140, doi: . <div id="Ehlert--2018"></div> Ehlert, D. and K. Zickfeld, 2018: Irreversible ocean thermal expansion under carbon dioxide removal. ''Earth System Dynamics'' , '''9(1)''' , 197–210, doi: . <div id="Ekholm--2016"></div> Ekholm, T. and H. Korhonen, 2016: Climate change mitigation strategy under an uncertain Solar Radiation Management possibility. ''Climatic Change'' , '''139(3)''' , 503–515, doi: . <div id="Emori--2005"></div> Emori, S. and S.J. Brown, 2005: Dynamic and thermodynamic changes in mean and extreme precipitation under changed climate. ''Geophysical Research Letters'' , '''32(17)''' , L17706, doi: . <div id="Endo--2018"></div> Endo, H., A. Kitoh, and H. Ueda, 2018: A Unique Feature of the Asian Summer Monsoon Response to Global Warming: The Role of Different Land–Sea Thermal Contrast Change between the Lower and Upper Troposphere. ''SOLA'' , '''14''' , 57–63, doi: . <div id="Engelbrecht--2015"></div> Engelbrecht, F. et al., 2015: Projections of rapidly rising surface temperatures over Africa under low mitigation. ''Environmental Research Letters'' , '''10(8)''' , 085004, doi: . <div id="Etminan--2016"></div> Etminan, M., G. Myhre, E.J. Highwood, and K.P. Shine, 2016: Radiative forcing of carbon dioxide, methane, and nitrous oxide: A significant revision of the methane radiative forcing. ''Geophysical Research Letters'' , '''43(24)''' , 12,614–12,623, doi: . <div id="Evans--2010"></div> Evans, J.R.G., E.P.J. Stride, M.J. Edirisinghe, D.J. Andrews, and R.R. Simons, 2010: Can oceanic foams limit global warming? ''Climate Research'' , '''42(2)''' , 155–160, doi: . <div id="Evin--2019"></div> Evin, G. et al., 2019: Partitioning uncertainty components of an incomplete ensemble of climate projections using data augmentation. ''Journal of Climate'' , '''32(8)''' , 2423–2440, doi: . <div id="Eyring--2013"></div> Eyring, V. et al., 2013: Long-term ozone changes and associated climate impacts in CMIP5 simulations. ''Journal of Geophysical Research: Atmospheres'' , '''118(10)''' , 5029–5060, doi: . <div id="Eyring--2016"></div> Eyring, V. et al., 2016: Overview of the Coupled Model Intercomparison Project Phase 6 (CMIP6) experimental design and organization. ''Geoscientific Model Development'' , '''9(5)''' , 1937–1958, doi: . <div id="Fasullo--2015"></div> Fasullo, J.T., B.M. Sanderson, and K.E. Trenberth, 2015: Recent Progress in Constraining Climate Sensitivity With Model Ensembles. ''Current Climate Change Reports'' , '''1(4)''' , 268–275, doi: . <div id="Fasullo--2018"></div> Fasullo, J.T. et al., 2018: Persistent polar ocean warming in a strategically geoengineered climate. ''Nature Geoscience'' , '''11(12)''' , 910–914, doi: . <div id="Fedorov--2020"></div> Fedorov, A., S. Hu, A.T. Wittenberg, A.F.Z. Levine, and C. Deser, 2020: ENSO Low-Frequency Modulation and Mean State Interactions. In: ''El Niño Southern Oscillation in a Changing Climate'' [McPhaden, M., A. Santoso, and W. Cai (eds.)]. American Geophysical Union (AGU), Washington, DC, USA, pp. 173–198, doi: . <div id="Feldmann--2019"></div> Feldmann, J., A. Levermann, and M. Mengel, 2019: Stabilizing the West Antarctic Ice Sheet by surface mass deposition. ''Science Advances'' , '''5(7)''' , eaaw4132, doi: . <div id="Feng--2015"></div> Feng, H. and M. Zhang, 2015: Global land moisture trends: drier in dry and wetter in wet over land. ''Scientific Reports'' , '''5(1)''' , 18018, doi: . <div id="Ferraro--2016"></div> Ferraro, A.J. and H.G. Griffiths, 2016: Quantifying the temperature-independent effect of stratospheric aerosol geoengineering on global-mean precipitation in a multi-model ensemble. ''Environmental Research Letters'' , '''11(3)''' , 034012, doi: . <div id="Ferraro--2011"></div> Ferraro, A.J., E.J. Highwood, and A.J. Charlton-Perez, 2011: Stratospheric heating by potential geoengineering aerosols. ''Geophysical Research Letters'' , '''38(24)''' , 1–6, doi: . <div id="Ferraro--2015"></div> Ferraro, A.J., A.J. Charlton-Perez, and E.J. Highwood, 2015: Stratospheric dynamics and midlatitude jets under geoengineering with space mirrors and sulfate and titania aerosols. ''Journal of Geophysical Research: Atmospheres'' , '''120(2)''' , 414–429, doi: . <div id="Ferreira--2015"></div> Ferreira, D., J. Marshall, C.M. Bitz, S. Solomon, and A. Plumb, 2015: Antarctic ocean and sea ice response to ozone depletion: A two-time-scale problem. ''Journal of Climate'' , '''28(3)''' , 1206–1226, doi: . <div id="Ferro--2017"></div> Ferro, C.A.T., 2017: Measuring forecast performance in the presence of observation error. ''Quarterly Journal of the Royal Meteorological Society'' , '''143(708)''' , 2665–2676, doi: . <div id="Field--2018"></div> Field, L. et al., 2018: Increasing Arctic Sea Ice Albedo Using Localized Reversible Geoengineering. ''Earth’s Future'' , '''6(6)''' , 882–901, doi: . <div id="Finney--2018"></div> Finney, D.L. et al., 2018: A projected decrease in lightning under climate change. ''Nature Climate Change'' , '''8(3)''' , 210–213, doi: . <div id="Fischer--2014"></div> Fischer, E.M. and R. Knutti, 2014: Heated debate on cold weather. ''Nature Climate Change'' , '''4(7)''' , 537–538, doi: . <div id="Fischer--2011"></div> Fischer, E.M., D.M. Lawrence, and B.M. Sanderson, 2011: Quantifying uncertainties in projections of extremes – a perturbed land surface parameter experiment. ''Climate Dynamics'' , '''37(7–8)''' , 1381–1398, doi: . <div id="Fischer--2012"></div> Fischer, E.M., J. Rajczak, and C. Schär, 2012: Changes in European summer temperature variability revisited. ''Geophysical Research Letters'' , '''39''' , L19702, doi: . <div id="Fischer--2013"></div> Fischer, E.M., U. Beyerle, and R. Knutti, 2013: Robust spatially aggregated projections of climate extremes. ''Nature Climate Change'' , '''3''' , 1033–1038, doi: . <div id="Fischer--2014"></div> Fischer, E.M., J. Sedláček, E. Hawkins, and R. Knutti, 2014: Models agree on forced response pattern of precipitation and temperature extremes. ''Geophysical Research Letters'' , '''41(23)''' , 8554–8562, doi: . <div id="Fischer--2018"></div> Fischer, H. et al., 2018: Palaeoclimate constraints on the impact of 2°C anthropogenic warming and beyond. ''Nature Geoscience'' , '''11''' , 474–485, doi: . <div id="Fläschner--2016"></div> Fläschner, D., T. Mauritsen, and B. Stevens, 2016: Understanding the intermodel spread in global-mean hydrological sensitivity. ''Journal of Climate'' , '''29(2)''' , 801–817, doi: . <div id="Flato--2013"></div> Flato, G. et al., 2013: Evaluation of Climate Models. In: ''Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change'' [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 741–866, doi: . <div id="Flato--2011"></div> Flato, G.M., 2011: Earth system models: an overview. ''WIREs Climate Change'' , '''2(6)''' , 783–800, doi: . <div id="Folland--2002"></div> Folland, C.K., 2002: Relative influences of the Interdecadal Pacific Oscillation and ENSO on the South Pacific Convergence Zone. ''Geophysical Research Letters'' , '''29(13)''' , 1643, doi: . <div id="Forster--2020"></div> Forster, P.M., A.C. Maycock, C.M. McKenna, and C.J. Smith, 2020: Latest climate models confirm need for urgent mitigation. ''Nature Climate Change'' , '''10(1)''' , 7–10, doi: . <div id="Francis--2015"></div> Francis, J.A. and S.J. Vavrus, 2015: Evidence for a wavier jet stream in response to rapid Arctic warming. ''Environmental Research Letters'' , '''10(1)''' , 014005, doi: . <div id="Fransner--2020"></div> Fransner, F. et al., 2020: Ocean Biogeochemical Predictions – Initialization and Limits of Predictability. ''Frontiers in Marine Science'' , '''7''' , 386, doi: . <div id="Fredriksen--2020"></div> Fredriksen, H.-B., J. Berner, A.C. Subramanian, and A. Capotondi, 2020: How Does El Niño-Southern Oscillation Change Under Global Warming – A First Look at CMIP6. ''Geophysical Research Letters'' , '''47(22)''' , e2020GL090640, doi: . <div id="Freund--2020"></div> Freund, M.B., J.N.J.R. Brown, B.J. Henley, D.J. Karoly, and J.N.J.R. Brown, 2020: Warming Patterns Affect El Niño Diversity in CMIP5 and CMIP6 Models. ''Journal of Climate'' , '''33(19)''' , 8237–8260, doi: . <div id="Friedlingstein--2014"></div> Friedlingstein, P. et al., 2014: Uncertainties in CMIP5 climate projections due to carbon cycle feedbacks. ''Journal of Climate'' , '''27(2)''' , 511–526, doi: . <div id="Frieler--2012"></div> Frieler, K., M. Meinshausen, M. Mengel, N. Braun, and W. Hare, 2012: A scaling approach to probabilistic assessment of regional climate change. ''Journal of Climate'' , '''25(9)''' , 3117–3144, doi: . <div id="Frisch--2015"></div> Frisch, M., 2015: Predictivism and old evidence: a critical look at climate model tuning. ''European Journal for Philosophy of Science'' , '''5(2)''' , 171–190, doi: . <div id="Frölicher--2015"></div> Frölicher, T.L. and D.J. Paynter, 2015: Extending the relationship between global warming and cumulative carbon emissions to multi-millennial timescales. ''Environmental Research Letters'' , '''10(7)''' , 075002, doi: . <div id="Frölicher--2014"></div> Frölicher, T.L., M. Winton, and J.L. Sarmiento, 2014: Continued global warming after CO <sub>2</sub> emissions stoppage. ''Nature Climate Change'' , '''4(1)''' , 40–44, doi: . <div id="Frölicher--2015"></div> Frölicher, T.L. et al., 2015: Dominance of the Southern Ocean in Anthropogenic Carbon and Heat Uptake in CMIP5 Models. ''Journal of Climate'' , '''28(2)''' , 862–886, doi: . <div id="Fu--2014"></div> Fu, Q. and S. Feng, 2014: Responses of terrestrial aridity to global warming. ''Journal of Geophysical Research: Atmospheres'' , '''119(13)''' , 7863–7875, doi: . <div id="Fu--2015"></div> Fu, Q., P. Lin, S. Solomon, and D.L. Hartmann, 2015: Observational evidence of strengthening of the Brewer-Dobson circulation since 1980. ''Journal of Geophysical Research: Atmospheres'' , '''120(19)''' , 10214–10228, doi: . <div id="Fu--2019"></div> Fu, Q., S. Solomon, H.A. Pahlavan, and P. Lin, 2019: Observed changes in Brewer-Dobson circulation for 1980–2018. ''Environmental Research Letters'' , '''14(11)''' , 114026, doi: . <div id="Fučkar--2014"></div> Fučkar, N.S., D. Volpi, V. Guemas, and F.J. Doblas-Reyes, 2014: A posteriori adjustment of near-term climate predictions: Accounting for the drift dependence on the initial conditions. ''Geophysical Research Letters'' , '''41(14)''' , 5200–5207, doi: . <div id="Fujita--2019"></div> Fujita, M. et al., 2019: Precipitation Changes in a Climate With 2-K Surface Warming From Large Ensemble Simulations Using 60-km Global and 20-km Regional Atmospheric Models. ''Geophysical Research Letters'' , '''46(1)''' , 435–442, doi: . <div id="Fuss--2018"></div> Fuss, S. et al., 2018: Negative emissions – Part 2: Costs, potentials and side effects. ''Environmental Research Letters'' , '''13(6)''' , 063002, doi: . <div id="Fyfe--1999"></div> Fyfe, J.C., G.J. Boer, and G.M. Flato, 1999: The Arctic and Antarctic oscillations and their projected changes under global warming. ''Geophysical Research Letters'' , '''26(11)''' , 1601–1604, doi: . <div id="Gabriel--2017"></div> Gabriel, C.J., A. Robock, L. Xia, B. Zambri, and B. Kravitz, 2017: The G4Foam Experiment: global climate impacts of regional ocean albedo modification. ''Atmospheric Chemistry and Physics'' , '''17(1)''' , 595–613, doi: . <div id="Gagné--2015"></div> Gagné, M.-È., N.P. Gillett, and J.C. Fyfe, 2015: Impact of aerosol emission controls on future Arctic sea ice cover. ''Geophysical Research Letters'' , '''42(20)''' , 8481–8488, doi: . <div id="Gagné--2017a"></div> Gagné, M.-È., M.C. Kirchmeier-Young, N.P. Gillett, and J.C. Fyfe, 2017a: Arctic sea ice response to the eruptions of Agung, El Chichón, and Pinatubo. ''Journal of Geophysical Research: Atmospheres'' , '''122(15)''' , 8071–8078, doi: . <div id="Gagné--2017b"></div> Gagné, M.-È., J.C. Fyfe, N.P. Gillett, I. Polyakov, and G.M. Flato, 2017b: Aerosol-driven increase in Arctic sea ice over the middle of the twentieth century. ''Geophysical Research Letters'' , '''44(14)''' , 7338–7346, doi: . <div id="García-Serrano--2015"></div> García-Serrano, J., V. Guemas, and F.J. Doblas-Reyes, 2015: Added-value from initialization in predictions of Atlantic multi-decadal variability. ''Climate Dynamics'' , '''44(9–10)''' , 2539–2555, doi: . <div id="Gasparini--2016"></div> Gasparini, B. and U. Lohmann, 2016: Why cirrus cloud seeding cannot substantially cool the planet. ''Journal of Geophysical Research: Atmospheres'' , '''121(9)''' , 4877–4893, doi: . <div id="Gasparini--2020"></div> Gasparini, B., Z. McGraw, T. Storelvmo, and U. Lohmann, 2020: To what extent can cirrus cloud seeding counteract global warming? ''Environmental Research Letters'' , '''15(5)''' , 54002, doi: . <div id="Gasparini--2017"></div> Gasparini, B., S. Münch, L. Poncet, M. Feldmann, and U. Lohmann, 2017: Is increasing ice crystal sedimentation velocity in geoengineering simulations a good proxy for cirrus cloud seeding? ''Atmospheric Chemistry and Physics'' , '''17(7)''' , 4871–4885, doi: . <div id="Geden--2017"></div> Geden, O. and A. Loeschel, 2017: Define limits for temperature overshoot targets. ''Nature Geoscience'' , '''10(12)''' , 881–882, doi: . <div id="Geng--2019"></div> Geng, T., Y. Yang, and L. Wu, 2019: On the Mechanisms of Pacific Decadal Oscillation Modulation in a Warming Climate. ''Journal of Climate'' , '''32(5)''' , 1443–1459, doi: . <div id="Gertler--2020"></div> Gertler, C.G. et al., 2020: Weakening of the Extratropical Storm Tracks in Solar Geoengineering Scenarios. ''Geophysical Research Letters'' , '''47(11)''' , e2020GL087348, doi: . <div id="Gidden--2019"></div> Gidden, M.J. et al., 2019: Global emissions pathways under different socioeconomic scenarios for use in CMIP6: a dataset of harmonized emissions trajectories through the end of the century. ''Geoscientific Model Development'' , '''12(4)''' , 1443–1475, doi: . <div id="Gillett--2013"></div> Gillett, N.P. and J.C. Fyfe, 2013: Annular mode changes in the CMIP5 simulations. ''Geophysical Research Letters'' , '''40(6)''' , 1189–1193, doi: . <div id="Gillett--2013"></div> Gillett, N.P., V.K. Arora, D. Matthews, and M.R. Allen, 2013: Constraining the Ratio of Global Warming to Cumulative CO <sub>2</sub> emissions Using CMIP5 Simulations. ''Journal of Climate'' , '''26(18)''' , 6844–6858, doi: . <div id="Gillett--2021"></div> Gillett, N.P. et al., 2021: Constraining human contributions to observed warming since the pre-industrial period. ''Nature Climate Change'' , '''11(3)''' , 207–212, doi: . <div id="Giorgi--2016"></div> Giorgi, F. et al., 2016: Enhanced summer convective rainfall at Alpine high elevations in response to climate warming. ''Nature Geoscience'' , '''9(8)''' , 584–589, doi: . <div id="Goddard--2013"></div> Goddard, L. et al., 2013: A verification framework for interannual-to-decadal predictions experiments. ''Climate Dynamics'' , '''40(1–2)''' , 245–272, doi: . <div id="Golledge--2019"></div> Golledge, N.R. et al., 2019: Global environmental consequences of twenty-first-century ice-sheet melt. ''Nature'' , '''566(7742)''' , 65–72, doi: . <div id="Gong--1999"></div> Gong, D. and S. Wang, 1999: Definition of Antarctic Oscillation index. ''Geophysical Research Letters'' , '''26(4)''' , 459–462, doi: . <div id="González--2018"></div> González, M.F., T. Ilyina, S. Sonntag, and H. Schmidt, 2018: Enhanced Rates of Regional Warming and Ocean Acidification After Termination of Large-Scale Ocean Alkalinization. ''Geophysical Research Letters'' , '''45(14)''' , 7120–7129, doi: . <div id="Good--2015"></div> Good, P. et al., 2015: Nonlinear regional warming with increasing CO <sub>2</sub> concentrations. ''Nature Climate Change'' , '''5''' , 138–142, doi: . <div id="Good--2016"></div> Good, P. et al., 2016: Large differences in regional precipitation change between a first and second 2 K of global warming. ''Nature Communications'' , '''7''' , 13667, doi: . <div id="Good--2018"></div> Good, P. et al., 2018: Recent progress in understanding climate thresholds. ''Progress in Physical Geography: Earth and Environment'' , '''42(1)''' , 24–60, doi: . <div id="Goodman--1999"></div> Goodman, J. and J. Marshall, 1999: A Model of Decadal Middle-Latitude Atmosphere–Ocean Coupled Modes. ''Journal of Climate'' , '''12(2)''' , 621–641, doi: . <div id="Goosse--2018"></div> Goosse, H. et al., 2018: Quantifying climate feedbacks in polar regions. ''Nature Communications'' , '''9(1)''' , 1919, doi: . <div id="Goyal--2021"></div> Goyal, R., A. Sen Gupta, M. Jucker, and M.H. England, 2021: Historical and Projected Changes in the Southern Hemisphere Surface Westerlies. ''Geophysical Research Letters'' , '''48''' , e2020GL090849, doi: . <div id="Graff--2014"></div> Graff, L.S. and J.H. LaCasce, 2014: Changes in Cyclone Characteristics in Response to Modified SSTs. ''Journal of Climate'' , '''27(11)''' , 4273–4295, doi: . <div id="Gregory--1995"></div> Gregory, J.M. and J.F.B. Mitchell, 1995: Simulation of daily variability of surface temperature and precipitation over europe in the current and 2 × CO <sub>2</sub> climates using the UKMO climate model. ''Quarterly Journal of the Royal Meteorological Society'' , '''121(526)''' , 1451–1476, doi: . <div id="Greve--2015"></div> Greve, P. and S.I. Seneviratne, 2015: Assessment of future changes in water availability and aridity. ''Geophysical Research Letters'' , '''42(13)''' , 5493–5499, doi: . <div id="Greve--2014"></div> Greve, P. et al., 2014: Global assessment of trends in wetting and drying over land. ''Nature Geoscience'' , '''7(10)''' , 716–721, doi: . <div id="Grieger--2014"></div> Grieger, J., G.C. Leckebusch, M.G. Donat, M. Schuster, and U. Ulbrich, 2014: Southern Hemisphere winter cyclone activity under recent and future climate conditions in multi-model AOGCM simulations. ''International Journal of Climatology'' , '''34(12)''' , 3400–3416, doi: . <div id="Grise--2014a"></div> Grise, K.M. and L.M. Polvani, 2014a: Is climate sensitivity related to dynamical sensitivity? A Southern Hemisphere perspective. ''Geophysical Research Letters'' , '''41(2)''' , 534–540, doi: . <div id="Grise--2014b"></div> Grise, K.M. and L.M. Polvani, 2014b: The response of midlatitude jets to increased CO <sub>2</sub> : Distinguishing the roles of sea surface temperature and direct radiative forcing. ''Geophysical Research Letters'' , '''41(19)''' , 6863–6871, doi: . <div id="Grise--2016"></div> Grise, K.M. and L.M. Polvani, 2016: Is climate sensitivity related to dynamical sensitivity? ''Journal of Geophysical Research: Atmospheres'' , '''121(10)''' , 5159–5176, doi: . <div id="Grise--2017"></div> Grise, K.M. and L.M. Polvani, 2017: Understanding the Time Scales of the Tropospheric Circulation Response to Abrupt CO <sub>2</sub> Forcing in the Southern Hemisphere: Seasonality and the Role of the Stratosphere. ''Journal of Climate'' , '''30(21)''' , 8497–8515, doi: . <div id="Gruber--2019"></div> Gruber, S. et al., 2019: A Process Study on Thinning of Arctic Winter Cirrus Clouds With High-Resolution ICON-ART Simulations. ''Journal of Geophysical Research: Atmospheres'' , '''124(11)''' , 5860–5888, doi: . <div id="Grubler--2001"></div> Grübler, A. and N. Nakicenovic, 2001: Identifying dangers in an uncertain climate. ''Nature'' , '''412(6842)''' , 15, doi: . <div id="Gryspeerdt--2019"></div> Gryspeerdt, E., T.W.P. Smith, E. O’Keeffe, M.W. Christensen, and F.W. Goldsworth, 2019: The Impact of Ship Emission Controls Recorded by Cloud Properties. ''Geophysical Research Letters'' , '''46(21)''' , 12547–12555, doi: . <div id="Guemas--2013"></div> Guemas, V. et al., 2013: The Indian Ocean: The Region of Highest Skill Worldwide in Decadal Climate Prediction. ''Journal of Climate'' , '''26(3)''' , 726–739, doi: . <div id="Guemas--2016"></div> Guemas, V. et al., 2016: A review on Arctic sea-ice predictability and prediction on seasonal to decadal time-scales. ''Quarterly Journal of the Royal Meteorological Society'' , '''142''' , 546–561, doi: . <div id="Haarsma--2009"></div> Haarsma, R.J., F. Selten, B. Hurk, W. Hazeleger, and X. Wang, 2009: Drier Mediterranean soils due to greenhouse warming bring easterly winds over summertime central Europe. ''Geophysical Research Letters'' , '''36(4)''' , L04705, doi: . <div id="Hall--2004"></div> Hall, A., 2004: The Role of Surface Albedo Feedback in Climate. ''Journal of Climate'' , '''17(7)''' , 1550–1568, doi: . <div id="Hall--2006"></div> Hall, A. and X. Qu, 2006: Using the current seasonal cycle to constrain snow albedo feedback in future climate change. ''Geophysical Research Letters'' , '''33(3)''' , L03502, doi: . <div id="Hand--2020"></div> Hand, R., J. Bader, D. Matei, R. Ghosh, and J.H. Jungclaus, 2020: Changes of Decadal SST Variations in the Subpolar North Atlantic under Strong CO <sub>2</sub> Forcing as an Indicator for the Ocean Circulation’s Contribution to Atlantic Multidecadal Variability. ''Journal of Climate'' , '''33(8)''' , 3213–3228, doi: . <div id="Hanna--2018"></div> Hanna, E., X. Fettweis, and R.J. Hall, 2018: Brief communication: Recent changes in summer Greenland blocking captured by none of the CMIP5 models. ''The Cryosphere'' , '''12(10)''' , 3287–3292, doi: . <div id="Hansen--1984"></div> Hansen, J. et al., 1984: Climate sensitivity: Analysis of feedback mechanisms. In: ''Climate Processes and Climate Sensitivity'' [Hansen, J.E. and T. Takahashi (eds.)]. American Geophysical Union (AGU), Washington, DC, USA, pp. 130–163, doi: . <div id="Hardiman--2014"></div> Hardiman, S.C., N. Butchart, and N. Calvo, 2014: The morphology of the Brewer-Dobson circulation and its response to climate change in CMIP5 simulations. ''Quarterly Journal of the Royal Meteorological Society'' , '''140(683)''' , 1958–1965, doi: . <div id="Harrington--2016"></div> Harrington, L.J. et al., 2016: Poorest countries experience earlier anthropogenic emergence of daily temperature extremes. ''Environmental Research Letters'' , '''11(5)''' , 055007, doi: . <div id="Hartmann--2013"></div> Hartmann, D.L. et al., 2013: Observations: Atmosphere and Surface. In: ''Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change'' [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 159–254, doi: . <div id="Harvey--2014"></div> Harvey, B.J., L.C. Shaffrey, and T.J. Woollings, 2014: Equator-to-pole temperature differences and the extra-tropical storm track responses of the CMIP5 climate models. ''Climate Dynamics'' , '''43(5–6)''' , 1171–1182, doi: . <div id="Harvey--2015"></div> Harvey, B.J., L.C. Shaffrey, and T.J. Woollings, 2015: Deconstructing the climate change response of the Northern Hemisphere wintertime storm tracks. ''Climate Dynamics'' , '''45(9–10)''' , 2847–2860, doi: . <div id="Harvey--2020"></div> Harvey, B.J., P. Cook, L.C. Shaffrey, and R. Schiemann, 2020: The Response of the Northern Hemisphere Storm Tracks and Jet Streams to Climate Change in the CMIP3, CMIP5, and CMIP6 Climate Models. ''Journal of Geophysical Research: Atmospheres'' , '''125(23)''' , e2020JD032701, doi: . <div id="Haszpra--2020"></div> Haszpra, T., M. Herein, and T. Bódai, 2020: Investigating ENSO and its teleconnections under climate change in an ensemble view – a new perspective. ''Earth System Dynamics'' , '''11(1)''' , 267–280, doi: . <div id="Hausfather--2020"></div> Hausfather, Z. and G.P. Peters, 2020: Emissions – the ‘business as usual’ story is misleading. ''Nature'' , '''577''' , 618–620, doi: . <div id="Hausfather--2020"></div> Hausfather, Z., H.F. Drake, T. Abbott, and G.A. Schmidt, 2020: Evaluating the performance of past climate model projections. ''Geophysical Research Letters'' , '''47(1)''' , e2019GL085378, doi: . <div id="Hawcroft--2018"></div> Hawcroft, M., E. Walsh, K. Hodges, and G. Zappa, 2018: Significantly increased extreme precipitation expected in Europe and North America from extratropical cyclones. ''Environmental Research Letters'' , '''13(12)''' , 124006, doi: . <div id="Hawkins--2009"></div> Hawkins, E. and R. Sutton, 2009: The Potential to Narrow Uncertainty in Regional Climate Predictions. ''Bulletin of the American Meteorological Society'' , '''90(8)''' , 1095–1108, doi: . <div id="Hawkins--2011"></div> Hawkins, E. and R. Sutton, 2011: The potential to narrow uncertainty in projections of regional precipitation change. ''Climate Dynamics'' , '''37(1)''' , 407–418, doi: . <div id="Hawkins--2012"></div> Hawkins, E. and R. Sutton, 2012: Time of emergence of climate signals. ''Geophysical Research Letters'' , '''39(1)''' , L01702, doi: . <div id="Hawkins--2016"></div> Hawkins, E. and R. Sutton, 2016: Connecting Climate Model Projections of Global Temperature Change with the Real World. ''Bulletin of the American Meteorological Society'' , '''97(6)''' , 963–980, doi: . <div id="Hawkins--2016"></div> Hawkins, E., R.S. Smith, J.M. Gregory, and D.A. Stainforth, 2016: Irreducible uncertainty in near-term climate projections. ''Climate Dynamics'' , '''46(11)''' , 3807–3819, doi: . <div id="Hazeleger--2010"></div> Hazeleger, W. et al., 2010: EC-Earth: A Seamless Earth-System Prediction Approach in Action. ''Bulletin of the American Meteorological Society'' , '''91(10)''' , 1357–1364, doi: . <div id="Hazeleger--2013"></div> Hazeleger, W. et al., 2013: Multiyear climate predictions using two initialization strategies. ''Geophysical Research Letters'' , '''40(9)''' , 1794–1798, doi: . <div id="He--2017"></div> He, J. and B.J. Soden, 2017: A re-examination of the projected subtropical precipitation decline. ''Nature Climate Change'' , '''7(1)''' , 53–57, doi: . <div id="He--2018"></div> He, J. et al., 2018: Precipitation Sensitivity to Local Variations in Tropical Sea Surface Temperature. ''Journal of Climate'' , '''31(22)''' , 9225–9238, doi: . <div id="He--2017"></div> He, Y. et al., 2017: Reduction of initial shock in decadal predictions using a new initialization strategy. ''Geophysical Research Letters'' , '''44(16)''' , 8538–8547, doi: . <div id="He--2020"></div> He, Y. et al., 2020: A new DRP-4DVar-based coupled data assimilation system for decadal predictions using a fast online localization technique. ''Climate Dynamics'' , '''54(7–8)''' , 3541–3559, doi: . <div id="Hedemann--2017"></div> Hedemann, C., T. Mauritsen, J. Jungclaus, and J. Marotzke, 2017: The subtle origins of surface-warming hiatuses. ''Nature Climate Change'' , '''7(5)''' , 336–339, doi: . <div id="Held--2006"></div> Held, I.M. and B.J. Soden, 2006: Robust Responses of the Hydrological Cycle to Global Warming. ''Journal of Climate'' , '''19(21)''' , 5686–5699, doi: . <div id="Held--2010"></div> Held, I.M. et al., 2010: Probing the Fast and Slow Components of Global Warming by Returning Abruptly to Preindustrial Forcing. ''Journal of Climate'' , '''23(9)''' , 2418–2427, doi: . <div id="Henley--2017"></div> Henley, B.J., 2017: Pacific decadal climate variability: Indices, patterns and tropical–extratropical interactions. ''Global and Planetary Change'' , '''155''' , 42–55, doi: . <div id="Herger--2015"></div> Herger, N., B.M. Sanderson, and R. Knutti, 2015: Improved pattern scaling approaches for the use in climate impact studies. ''Geophysical Research Letters'' , '''42(9)''' , 3486–3494, doi: . <div id="Hermanson--2014"></div> Hermanson, L. et al., 2014: Forecast cooling of the Atlantic subpolar gyre and associated impacts. ''Geophysical Research Letters'' , '''41(14)''' , 5167–5174, doi: . <div id="Hermanson--2020"></div> Hermanson, L. et al., 2020: Robust Multiyear Climate Impacts of Volcanic Eruptions in Decadal Prediction Systems. ''Journal of Geophysical Research: Atmospheres'' , '''125(9)''' , e2019JD031739, doi: . <div id="Hewitt--2016"></div> Hewitt, A.J. et al., 2016: Sources of Uncertainty in Future Projections of the Carbon Cycle. ''Journal of Climate'' , '''29(20)''' , 7203–7213, doi: . <div id="Hezel--2014"></div> Hezel, P.J., T. Fichefet, and F. Massonnet, 2014: Modeled Arctic sea ice evolution through 2300 in CMIP5 extended RCPs. ''The Cryosphere'' , '''8(4)''' , 1195–1204, doi: . <div id="Hienola--2018"></div> Hienola, A. et al., 2018: The impact of aerosol emissions on the 1.5°C pathways. ''Environmental Research Letters'' , '''13(4)''' , 044011, doi: . <div id="Hill--2012"></div> Hill, S. and Y. Ming, 2012: Nonlinear climate response to regional brightening of tropical marine stratocumulus. ''Geophysical Research Letters'' , '''39(15)''' , L15707, doi: . <div id="Hingray--2014"></div> Hingray, B. and M. Saïd, 2014: Partitioning Internal Variability and Model Uncertainty Components in a Multimember Multimodel Ensemble of Climate Projections. ''Journal of Climate'' , '''27(17)''' , 6779–6798, doi: . <div id="Hingray--2019"></div> Hingray, B., J. Blanchet, G. Evin, and J.P. Vidal, 2019: Uncertainty component estimates in transient climate projections: Precision of estimators in a single time or time series approach. ''Climate Dynamics'' , '''53(5–6)''' , 2501–2516, doi: . <div id="Ho--2019"></div> Ho, E., D. Budescu, V. Bosetti, D.P. van Vuuren, and K. Keller, 2019: Not all carbon dioxide emission scenarios are equally likely : a subjective expert assessment. ''Climatic Change'' , '''155(4)''' , 545–561, doi: . <div id="Hoegh-Guldberg--2018"></div> Hoegh-Guldberg, O. et al., 2018: Impacts of 1.5°C Global Warming on Natural and Human Systems. In: ''Global Warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the threat of climate change,'' ''sustainable development, and efforts to eradicate poverty'' [Masson-Delmotte, V., P. Zhai, H.-O. Pörtner, D. Roberts, J. Skea, P.R. Shukla, A. Pirani, W. Moufouma-Okia, C. Péan, R. Pidcock, S. Connors, J.B.R. Matthews, Y. Chen, X. Zhou, M.I. Gomis, E. Lonnoy, T. Maycock, M. Tignor, and T. Waterfield (eds.)]. In Press, pp. 175–312, . <div id="Hoerling--2011"></div> Hoerling, M. et al., 2011: On North American Decadal Climate for 2011–20. ''Journal of Climate'' , '''24(16)''' , 4519–4528, doi: . <div id="Holland--2003"></div> Holland, M.M. and C.M. Bitz, 2003: Polar amplification of climate change in coupled models. ''Climate Dynamics'' , '''21(3–4)''' , 221–232, doi: . <div id="Holmes--2016"></div> Holmes, C.R., T. Woollings, E. Hawkins, and H. de Vries, 2016: Robust Future Changes in Temperature Variability under Greenhouse Gas Forcing and the Relationship with Thermal Advection. ''Journal of Climate'' , '''29(6)''' , 2221–2236, doi: . <div id="Hong--2016"></div> Hong, Y., G. Liu, and J.-L.F. Li, 2016: Assessing the Radiative Effects of Global Ice Clouds Based on CloudSat and CALIPSO Measurements. ''Journal of Climate'' , '''29(21)''' , 7651–7674, doi: . <div id="Hong--2017"></div> Hong, Y. et al., 2017: Impact of the GeoMIP G1 sunshade geoengineering experiment on the Atlantic meridional overturning circulation. ''Environmental Research Letters'' , '''12(3)''' , 034009, doi: . <div id="Horowitz--2020"></div> Horowitz, H.M. et al., 2020: Effects of Sea Salt Aerosol Emissions for Marine Cloud Brightening on Atmospheric Chemistry: Implications for Radiative Forcing. ''Geophysical Research Letters'' , '''47(4)''' , e2019GL085838, doi: . <div id="Hoskins--2015"></div> Hoskins, B. and T. Woollings, 2015: Persistent Extratropical Regimes and Climate Extremes. ''Current Climate Change Reports'' , '''1(3)''' , 115–124, doi: . <div id="Hsu--2013"></div> Hsu, P.-C., T. Li, H. Murakami, and A. Kitoh, 2013: Future change of the global monsoon revealed from 19 CMIP5 models. ''Journal of Geophysical Research: Atmospheres'' , '''118(3)''' , 1247–1260, doi: . <div id="Huang--2015"></div> Huang, P. and S.-P. Xie, 2015: Mechanisms of change in ENSO-induced tropical Pacific rainfall variability in a warming climate. ''Nature Geoscience'' , '''8(12)''' , 922–926, doi: . <div id="Huntingford--2013"></div> Huntingford, C., P.D. Jones, V.N. Livina, T.M. Lenton, and P.M. Cox, 2013: No increase in global temperature variability despite changing regional patterns. ''Nature'' , '''500(7462)''' , 327–330, doi: . <div id="Hurd--2018"></div> Hurd, C.L., A. Lenton, B. Tilbrook, and P.W. Boyd, 2018: Current understanding and challenges for oceans in a higher-CO <sub>2</sub> world. ''Nature Climate Change'' , '''8(8)''' , 686–694, doi: . <div id="Hwang--2013"></div> Hwang, Y.-T., D.M.W. Frierson, and S.M. Kang, 2013: Anthropogenic sulfate aerosol and the southward shift of tropical precipitation in the late 20th century. ''Geophysical Research Letters'' , '''40(11)''' , 2845–2850, doi: . <div id="Iles--2014"></div> Iles, C.E. and G.C. Hegerl, 2014: The global precipitation response to volcanic eruptions in the CMIP5 models. ''Environmental Research Letters'' , '''9(10)''' , 104012, doi: . <div id="Iles--2015"></div> Iles, C.E. and G.C. Hegerl, 2015: Systematic change in global patterns of streamflow following volcanic eruptions. ''Nature Geoscience'' , '''8''' , 838–842, doi: . <div id="Iles--2013"></div> Iles, C.E., G.C. Hegerl, A.P. Schurer, and X. Zhang, 2013: The effect of volcanic eruptions on global precipitation. ''Journal of Geophysical Research: Atmospheres'' , '''118(16)''' , 8770–8786, doi: . <div id="Illing--2018"></div> Illing, S., C. Kadow, H. Pohlmann, and C. Timmreck, 2018: Assessing the impact of a future volcanic eruption on decadal predictions. ''Earth System Dynamics'' , '''9(2)''' , 701–715, doi: . <div id="IPCC--2013"></div> [[#IPCC--2013|IPCC, 2013]] : Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 1535 pp., doi: . <div id="IPCC--2014"></div> [[#IPCC--2014|IPCC, 2014]] : Climate Change 2014: Mitigation of Climate Change. Contribution of Working Group III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change [Edenhofer, O., R. Pichs-Madruga, Y. Sokona, E. Farahani, S. Kadner, K. Seyboth, A. Adler, I. Baum, S. Brunner, P. Eickemeier, B. Kriemann, J. Savolainen, S. Schlömer, C. Stechow, T. Zwickel, and J.C. Minx (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 1435 pp., doi: . <div id="IPCC--2018a"></div> [[#IPCC--2018a|IPCC, 2018a]] : Global Warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the threat of climate change, sustainable development, and efforts to eradicate poverty. [Masson-Delmotte, V., P. Zhai, H.-O. Pörtner, D. Roberts, J. Skea, P.R. Shukla, A. Pirani, W. Moufouma-Okia, C. Péan, R. Pidcock, S. Connors, J.B.R. Matthews, Y. Chen, X. Zhou, M.I. Gomis, E. Lonnoy, T. Maycock, M. Tignor, and T. Waterfield (eds.)]. In Press, 616 pp., . <div id="IPCC--2018b"></div> [[#IPCC--2018b|IPCC, 2018b]] : Summary for Policymakers. In: ''Global Warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the threat of climate change,'' ''sustainable development, and efforts to eradicate poverty'' [Masson-Delmotte, V., P. Zhai, H.-O. Pörtner, D. Roberts, J. Skea, P.R. Shukla, A. Pirani, W. Moufouma-Okia, C. Péan, R. Pidcock, S. Connors, J.B.R. Matthews, Y. Chen, X. Zhou, M.I. Gomis, E. Lonnoy, T. Maycock, M. Tignor, and T. Waterfield (eds.)]. In Press, pp. 3–24, . <div id="IPCC--2019"></div> [[#IPCC--2019|IPCC, 2019]] : IPCC Special Report on the Ocean and Cryosphere in a Changing Climate [Pörtner, H.-O., D.C. Roberts, V. Masson-Delmotte, P. Zhai, M. Tignor, E. Poloczanska, K. Mintenbeck, A. Alegria, M. Nicolai, A. Okem, J. Petzold, B. Rama, and N.M. Weyer (eds.)]. In Press, 755 pp., . <div id="Irvine--2020"></div> Irvine, P.J. and D.W. Keith, 2020: Halving warming with stratospheric aerosol geoengineering moderates policy-relevant climate hazards. ''Environmental Research Letters'' , '''15(4)''' , 44011, doi: . <div id="Irvine--2012"></div> Irvine, P.J., R.L. Sriver, and K. Keller, 2012: Tension between reducing sea-level rise and global warming through solar-radiation management. ''Nature Climate Change'' , '''2(2)''' , 97–100, doi: . <div id="Irvine--2016"></div> Irvine, P.J., B. Kravitz, M.G. Lawrence, and H. Muri, 2016: An overview of the Earth system science of solar geoengineering. ''WIREs Climate Change'' , '''7(6)''' , 815–833, doi: . <div id="Irvine--2019"></div> Irvine, P.J. et al., 2019: Halving warming with idealized solar geoengineering moderates key climate hazards. ''Nature Climate Change'' , '''9(4)''' , 295–299, doi: . <div id="Ishizaki--2013"></div> Ishizaki, Y. et al., 2013: Dependence of Precipitation Scaling Patterns on Emission Scenarios for Representative Concentration Pathways. ''Journal of Climate'' , '''26(22)''' , 8868–8879, doi: . <div id="Izumi--2013"></div> Izumi, K., P.J. Bartlein, and S.P. Harrison, 2013: Consistent large-scale temperature responses in warm and cold climates. ''Geophysical Research Letters'' , '''40''' , 1817–1823, doi: . <div id="Jackson--2014"></div> Jackson, L.C., N. Schaller, R.S. Smith, M.D. Palmer, and M. Vellinga, 2014: Response of the Atlantic meridional overturning circulation to a reversal of greenhouse gas increases. ''Climate dynamics'' , '''42(11–12)''' , 3323–3336. <div id="Jackson--2016"></div> Jackson, L.S., J.A. Crook, and P.M. Forster, 2016: An intensified hydrological cycle in the simulation of geoengineering by cirrus cloud thinning using ice crystal fall speed changes. ''Journal of Geophysical Research: Atmospheres'' , '''121(12)''' , 6822–6840, doi: . <div id="Jahn--2018"></div> Jahn, A., 2018: Reduced probability of ice-free summers for 1.5°C compared to 2°C warming. ''Nature Climate Change'' , '''8(5)''' , 409–413, doi: . <div id="James--2017"></div> James, R., R. Washington, C.-F. Schleussner, J. Rogelj, and D. Conway, 2017: Characterizing half-a-degree difference: a review of methods for identifying regional climate responses to global warming targets. ''WIREs Climate Change'' , '''8(2)''' , e457, doi: . <div id="Jeffrey--2013"></div> Jeffrey, S. et al., 2013: Australia’s CMIP5 submission using the CSIRO-Mk3.6 model. ''Australian Meteorological and Oceanographic Journal'' , '''63(1)''' , 1–14, doi: . <div id="Jeltsch-Thömmes--2020"></div> Jeltsch-Thömmes, A., T.F. Stocker, and F. Joos, 2020: Hysteresis of the Earth system under positive and negative CO <sub>2</sub> emissions. ''Environmental Research Letters'' , '''15(12)''' , 124026, doi: . <div id="Ji--2018"></div> Ji, D. et al., 2018: Extreme temperature and precipitation response to solar dimming and stratospheric aerosol geoengineering. ''Atmospheric Chemistry and Physics'' , '''18(14)''' , 10133–10156, doi: . <div id="Jia--2019"></div> Jia, F. et al., 2019: Weakening Atlantic Niño–Pacific connection under greenhouse warming. ''Science Advances'' , '''5(8)''' , eaax4111, doi: . <div id="Jia--2019"></div> Jia, G. et al., 2019: Land–climate interactions. In: ''Climate Change and Land: an IPCC special report on climate change, desertification, land degradation, sustainable land management, food security, and greenhouse gas fluxes in terrestrial ecosystems'' [Shukla, P.R., J. Skea, E.C. Buendia, V. Masson-Delmotte, H.-O. Pörtner, D.C. Roberts, P. Zhai, R. Slade, S. Connors, R. Diemen, M. Ferrat, E. Haughey, S. Luz, S. Neogi, M. Pathak, J. Petzold, J.P. Pereira, P. Vyas, E. Huntley, K. Kissick, M. Belkacemi, and J. Malley (eds.)]. In Press, pp. 131–248, . <div id="Jiang--2019"></div> Jiang, J. et al., 2019: Stratospheric Sulfate Aerosol Geoengineering Could Alter the High-Latitude Seasonal Cycle. ''Geophysical Research Letters'' , '''46(23)''' , 14153–14163, doi: . <div id="Jiaxiang--2020"></div> Jiaxiang, G. et al., 2020: Influence of model resolution on bomb cyclones revealed by HighResMIP-PRIMAVERA simulations. ''Environmental Research Letters'' , '''15(8)''' , 084001, doi: . <div id="Jiménez-de-la-Cuesta--2019"></div> Jiménez-de-la-Cuesta, D. and T. Mauritsen, 2019: Emergent constraints on Earth’s transient and equilibrium response to doubled CO <sub>2</sub> from post-1970s global warming. ''Nature Geoscience'' , '''12(11)''' , 902–905, doi: . <div id="Johnson--2018"></div> Johnson, J.S. et al., 2018: The importance of comprehensive parameter sampling and multiple observations for robust constraint of aerosol radiative forcing. ''Atmospheric Chemistry and Physics'' , '''18(17)''' , 13031–13053, doi: . <div id="Jones--2013"></div> Jones, A. et al., 2013: The impact of abrupt suspension of solar radiation management (termination effect) in experiment G2 of the Geoengineering Model Intercomparison Project (GeoMIP). ''Journal of Geophysical Research: Atmospheres'' , '''118(17)''' , 9743–9752, doi: . <div id="Jones--2021"></div> Jones, A. et al., 2021: North Atlantic Oscillation response in GeoMIP experiments G6solar and G6sulfur: why detailed modelling is needed for understanding regional implications of solar radiation management. ''Atmospheric Chemistry and Physics'' , '''21(2)''' , 1287–1304, doi: . <div id="Jones--2016"></div> Jones, A.C., J.M. Haywood, and A. Jones, 2016: Climatic impacts of stratospheric geoengineering with sulfate, black carbon and titania injection. ''Atmospheric Chemistry and Physics'' , '''16(5)''' , 2843–2862, doi: . <div id="Jones--2017"></div> Jones, A.C. et al., 2017: Impacts of hemispheric solar geoengineering on tropical cyclone frequency. ''Nature Communications'' , '''8(1)''' , 1382, doi: . <div id="Jones--2018"></div> Jones, A.C. et al., 2018: Regional Climate Impacts of Stabilizing Global Warming at 1.5 K Using Solar Geoengineering. ''Earth’s Future'' , '''6(2)''' , 230–251, doi: . <div id="Jones--2020"></div> Jones, C.D. and P. Friedlingstein, 2020: Quantifying process-level uncertainty contributions to TCRE and carbon budgets for meeting Paris Agreement climate targets. ''Environmental Research Letters'' , '''15(7)''' , 074019, doi: . <div id="Jones--2016a"></div> Jones, C.D. et al., 2016a: C4MIP – The Coupled Climate–Carbon Cycle Model Intercomparison Project: experimental protocol for CMIP6. ''Geoscientific Model Development'' , '''9(8)''' , 2853–2880, doi: . <div id="Jones--2016b"></div> Jones, C.D. et al., 2016b: Simulating the Earth system response to negative emissions. ''Environmental Research Letters'' , '''11(9)''' , 095012, doi: . <div id="Jones--2019"></div> Jones, C.D. et al., 2019: The Zero Emissions Commitment Model Intercomparison Project (ZECMIP) contribution to C4MIP: quantifying committed climate changes following zero carbon emissions. ''Geoscientific Model Development'' , '''12(10)''' , 4375–4385, doi: . <div id="Joos--2013"></div> Joos, F. et al., 2013: Carbon dioxide and climate impulse response functions for the computation of greenhouse gas metrics: a multi-model analysis. ''Atmospheric Chemistry and Physics'' , '''13(5)''' , 2793–2825, doi: . <div id="Joshi--2008"></div> Joshi, M.M. and J. Gregory, 2008: Dependence of the land–sea contrast in surface climate response on the nature of the forcing. ''Geophysical Research Letters'' , '''35(24)''' , L24802, doi: . <div id="Joshi--2013"></div> Joshi, M.M., F.H. Lambert, and M.J. Webb, 2013: An explanation for the difference between twentieth and twenty-first century land–sea warming ratio in climate models. ''Climate Dynamics'' , '''41(7–8)''' , 1853–1869, doi: . <div id="Joshi--2008"></div> Joshi, M.M., J.M. Gregory, M.J. Webb, D.M.H. Sexton, and T.C. Johns, 2008: Mechanisms for the land/sea warming contrast exhibited by simulations of climate change. ''Climate Dynamics'' , '''30(5)''' , 455–465, doi: . <div id="Jungclaus--2010"></div> Jungclaus, J.H. et al., 2010: Climate and carbon-cycle variability over the last millennium. ''Climate of the Past'' , '''6(5)''' , 723–737, doi: . <div id="Juricke--2018"></div> Juricke, S., D. MacLeod, A. Weisheimer, L. Zanna, and T.N. Palmer, 2018: Seasonal to annual ocean forecasting skill and the role of model and observational uncertainty. ''Quarterly Journal of the Royal Meteorological Society'' , '''144(715)''' , 1947–1964, doi: . <div id="Kadow--2017"></div> Kadow, C., S. Illing, I. Kröner, U. Ulbrich, and U. Cubasch, 2017: Decadal climate predictions improved by ocean ensemble dispersion filtering. ''Journal of Advances in Modeling Earth Systems'' , '''9(2)''' , 1138–1149, doi: . <div id="Kalidindi--2015"></div> Kalidindi, S., G. Bala, A. Modak, and K. Caldeira, 2015: Modeling of solar radiation management: a comparison of simulations using reduced solar constant and stratospheric sulphate aerosols. ''Climate Dynamics'' , '''44(9–10)''' , 2909–2925, doi: . <div id="Kamae--2012"></div> Kamae, Y. and M. Watanabe, 2012: On the robustness of tropospheric adjustment in CMIP5 models. ''Geophysical Research Letters'' , '''39(23)''' , L23808, doi: . <div id="Kamae--2013"></div> Kamae, Y. and M. Watanabe, 2013: Tropospheric adjustment to increasing CO <sub>2</sub> : Its timescale and the role of land–sea contrast. ''Climate Dynamics'' , '''41(11–12)''' , 3007–3024, doi: . <div id="Karspeck--2015"></div> Karspeck, A.R., S. Yeager, G. Danabasoglu, and H. Teng, 2015: An evaluation of experimental decadal predictions using CCSM4. ''Climate Dynamics'' , '''44(3)''' , 907–923, doi: . <div id="Karspeck--2017"></div> Karspeck, A.R. et al., 2017: Comparison of the Atlantic meridional overturning circulation between 1960 and 2007 in six ocean reanalysis products. ''Climate Dynamics'' , '''49(3)''' , 957–982, doi: . <div id="Kasoar--2018"></div> Kasoar, M., D. Shawki, and A. Voulgarakis, 2018: Similar spatial patterns of global climate response to aerosols from different regions. ''npj Climate and Atmospheric Science'' , '''1(1)''' , 12, doi: . <div id="Kay--2015"></div> Kay, J.E. et al., 2015: The Community Earth System Model (CESM) Large Ensemble Project: A Community Resource for Studying Climate Change in the Presence of Internal Climate Variability. ''Bulletin of the American Meteorological Society'' , '''96(8)''' , 1333–1349, doi: . <div id="Keenlyside--2008"></div> Keenlyside, N.S., M. Latif, J. Jungclaus, L. Kornblueh, and E. Roeckner, 2008: Advancing decadal-scale climate prediction in the North Atlantic sector. ''Nature'' , '''453(7191)''' , 84–88, doi: . <div id="Keith--2010"></div> Keith, D.W., 2010: Photophoretic levitation of engineered aerosols for geoengineering. ''Proceedings of the National Academy of Sciences'' , '''107(38)''' , 16428–16431, doi: . <div id="Keith--2015"></div> Keith, D.W. and D.G. MacMartin, 2015: A temporary, moderate and responsive scenario for solar geoengineering. ''Nature Climate Change'' , '''5(3)''' , 201–206, doi: . <div id="Keith--2016"></div> Keith, D.W., D.K. Weisenstein, J.A. Dykema, and F.N. Keutsch, 2016: Stratospheric solar geoengineering without ozone loss. ''Proceedings of the National Academy of Sciences'' , '''113(52)''' , 14910–14914, doi: . <div id="Keller--2014"></div> Keller, D.P., E.Y. Feng, and A. Oschlies, 2014: Potential climate engineering effectiveness and side effects during a high carbon dioxide-emission scenario. ''Nature Communications'' , '''5(1)''' , 3304, doi: . <div id="Keller--2018"></div> Keller, D.P. et al., 2018: The Carbon Dioxide Removal Model Intercomparison Project (CDRMIP): rationale and experimental protocol for CMIP6. ''Geoscientific Model Development'' , '''11(3)''' , 1133–1160, doi: . <div id="Kendon--2014"></div> Kendon, E.J. et al., 2014: Heavier summer downpours with climate change revealed by weather forecast resolution model. ''Nature Climate Change'' , '''4(7)''' , 570–576, doi: . <div id="Kennedy--2016"></div> Kennedy, D., T. Parker, T. Woollings, B. Harvey, and L. Shaffrey, 2016: The response of high-impact blocking weather systems to climate change. ''Geophysical Research Letters'' , '''43(13)''' , 7250–7258, doi: . <div id="Kent--2015"></div> Kent, C., R. Chadwick, and D.P. Rowell, 2015: Understanding Uncertainties in Future Projections of Seasonal Tropical Precipitation. ''Journal of Climate'' , '''28(11)''' , 4390–4413, doi: . <div id="Kharin--2012"></div> Kharin, V., G.J. Boer, W.J. Merryfield, J.F. Scinocca, and W.-S. Lee, 2012: Statistical adjustment of decadal predictions in a changing climate. ''Geophysical Research Letters'' , '''39(19)''' , L19705, doi: . <div id="Kharin--2018"></div> Kharin, V. et al., 2018: Risks from Climate Extremes Change Differently from 1.5°C to 2.0°C Depending on Rarity. ''Earth’s Future'' , '''6(5)''' , 704–715, doi: . <div id="Khodri--2017"></div> Khodri, M. et al., 2017: Tropical explosive volcanic eruptions can trigger El Ninõ by cooling tropical Africa. ''Nature Communications'' , '''8(1)''' , 1–12, doi: . <div id="Kidston--2010"></div> Kidston, J. and E.P. Gerber, 2010: Intermodel variability of the poleward shift of the austral jet stream in the CMIP3 integrations linked to biases in 20th century climatology. ''Geophysical Research Letters'' , '''37(9)''' , 1–5, doi: . <div id="Kilbourne--2014"></div> Kilbourne, K.H., M.A. Alexander, and J.A. Nye, 2014: A low latitude paleoclimate perspective on Atlantic multidecadal variability. ''Journal of Marine Systems'' , '''133''' , 4–13, doi: . <div id="Kim--2014"></div> Kim, S.T. et al., 2014: Response of El Niño sea surface temperature variability to greenhouse warming. ''Nature Climate Change'' , '''4(9)''' , 786–790, doi: . <div id="Kim--2020"></div> Kim, W.M., S. Yeager, and G. Danabasoglu, 2020: Atlantic Multidecadal Variability and Associated Climate Impacts Initiated by Ocean Thermohaline Dynamics. ''Journal of Climate'' , '''33(4)''' , 1317–1334, doi: . <div id="Kimmritz--2018"></div> Kimmritz, M. et al., 2018: Optimising assimilation of sea ice concentration in an Earth system model with a multicategory sea ice model. ''Tellus A: Dynamic Meteorology and Oceanography'' , '''70(1)''' , 1–23, doi: . <div id="Kirchmeier-Young--2017"></div> Kirchmeier-Young, M.C., F.W. Zwiers, and N.P. Gillett, 2017: Attribution of Extreme Events in Arctic Sea Ice Extent. ''Journal of Climate'' , '''30(2)''' , 553–571, doi: . <div id="Kirchmeier-Young--2019"></div> Kirchmeier-Young, M.C., H. Wan, X. Zhang, and S.I. Seneviratne, 2019: Importance of Framing for Extreme Event Attribution: The Role of Spatial and Temporal Scales. ''Earth’s Future'' , '''7(10)''' , 1192–1204, doi: . <div id="Kirtman--2013"></div> Kirtman, B. et al., 2013: Near-term climate change: projections and predictability. In: ''Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change'' [Stocker, T.F., D. Qin, G.-K. Plattner, M. Tignor, S.K. Allen, J. Boschung, A. Nauels, Y. Xia, V. Bex, and P.M. Midgley (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 953–1028, doi: . <div id="Kitano--2016"></div> Kitano, Y. and T.J. Yamada, 2016: Relationship between atmospheric blocking and cold day extremes in current and RCP8.5 future climate conditions over Japan and the surrounding area. ''Atmospheric Science Letters'' , '''17(11)''' , 616–622, doi: . <div id="Kitoh--2013"></div> Kitoh, A. et al., 2013: Monsoons in a changing world: A regional perspective in a global context. ''Journal of Geophysical Research: Atmospheres'' , '''118(8)''' , 3053–3065, doi: . <div id="Kjellström--2018"></div> Kjellström, E. et al., 2018: European climate change at global mean temperature increases of 1.5 and 2°C above pre-industrial conditions as simulated by the EURO-CORDEX regional climate models. ''Earth System Dynamics'' , '''9(2)''' , 459–478, doi: . <div id="Kleinschmitt--2018"></div> Kleinschmitt, C., O. Boucher, and U. Platt, 2018: Sensitivity of the radiative forcing by stratospheric sulfur geoengineering to the amount and strategy of the SO <sub>2</sub> injection studied with the LMDZ-S3A model. ''Atmospheric Chemistry and Physics'' , '''18(4)''' , 2769–2786, doi: . <div id="Klus--2018"></div> Klus, A., M. Prange, V. Varma, L.B. Tremblay, and M. Schulz, 2018: Abrupt cold events in the North Atlantic Ocean in a transient Holocene simulation. ''Climate of the Past'' , '''14(8)''' , 1165–1178, doi: . <div id="Knight--2014"></div> Knight, J.R. et al., 2014: Predictions of Climate Several Years Ahead Using an Improved Decadal Prediction System. ''Journal of Climate'' , '''27(20)''' , 7550–7567, doi: . <div id="Knudsen--2011"></div> Knudsen, M.F., M.-S. Seidenkrantz, B.H. Jacobsen, and A. Kuijpers, 2011: Tracking the Atlantic Multidecadal Oscillation through the last 8,000 years. ''Nature Communications'' , '''2(1)''' , 178, doi: . <div id="Knutti--2013"></div> Knutti, R. and J. Sedláček, 2013: Robustness and uncertainties in the new CMIP5 climate model projections. ''Nature Climate Change'' , '''3(4)''' , 369–373, doi: . <div id="Knutti--2013"></div> Knutti, R., D. Masson, and A. Gettelman, 2013: Climate model genealogy: Generation CMIP5 and how we got there. ''Geophysical Research Letters'' , '''40(6)''' , 1194–1199, doi: . <div id="Knutti--2010"></div> Knutti, R., R. Furrer, C. Tebaldi, J. Cermak, and G. Meehl, 2010: Challenges in Combining Projections from Multiple Climate Models. ''Journal of Climate'' , '''23(10)''' , 2739–2758, doi: . <div id="Knutti--2017"></div> Knutti, R. et al., 2017: A climate model projection weighting scheme accounting for performance and interdependence. ''Geophysical Research Letters'' , '''44(4)''' , 1909–1918, doi: . <div id="Kobashi--2017"></div> Kobashi, T. et al., 2017: Volcanic influence on centennial to millennial Holocene Greenland temperature change. ''Scientific Reports'' , '''7(1)''' , 1–10, doi: . <div id="Koenigk--2014"></div> Koenigk, T., A. Devasthale, and K.G. Karlsson, 2014: Summer arctic sea ice albedo in CMIP5 models. ''Atmospheric Chemistry and Physics'' , '''14(4)''' , 1987–1998, doi: . <div id="Kohyama--2017"></div> Kohyama, T. and D.L. Hartmann, 2017: Nonlinear ENSO Warming Suppression (NEWS). ''Journal of Climate'' , '''30(11)''' , 4227–4251, doi: . <div id="Kosaka--2016"></div> Kosaka, Y. and S.-P. Xie, 2016: The tropical Pacific as a key pacemaker of the variable rates of global warming. ''Nature Geoscience'' , '''9(9)''' , 669–673, doi: . <div id="Kostov--2017"></div> Kostov, Y. et al., 2017: Fast and slow responses of Southern Ocean sea surface temperature to SAM in coupled climate models. ''Climate Dynamics'' , '''48(5–6)''' , 1595–1609, doi: . <div id="Kravitz--2016"></div> Kravitz, B., D.G. MacMartin, H. Wang, and P.J. Rasch, 2016: Geoengineering as a design problem. ''Earth System Dynamics'' , '''7(2)''' , 469–497, doi: . <div id="Kravitz--2011"></div> Kravitz, B. et al., 2011: The Geoengineering Model Intercomparison Project (GeoMIP). ''Atmospheric Science Letters'' , '''12(2)''' , 162–167, doi: . <div id="Kravitz--2013a"></div> Kravitz, B. et al., 2013a: Climate model response from the Geoengineering Model Intercomparison Project (GeoMIP). ''Journal of Geophysical Research: Atmospheres'' , '''118(15)''' , 8320–8332, doi: . <div id="Kravitz--2013b"></div> Kravitz, B. et al., 2013b: Sea spray geoengineering experiments in the geoengineering model intercomparison project (GeoMIP): Experimental design and preliminary results. ''Journal of Geophysical Research: Atmospheres'' , '''118(19)''' , 11175–11186, doi: . <div id="Kravitz--2014"></div> Kravitz, B. et al., 2014: A multi-model assessment of regional climate disparities caused by solar geoengineering. ''Environmental Research Letters'' , '''9(7)''' , 074013, doi: . <div id="Kravitz--2015"></div> Kravitz, B. et al., 2015: The Geoengineering Model Intercomparison Project Phase 6 (GeoMIP6): simulation design and preliminary results. ''Geoscientific Model Development'' , '''8(10)''' , 3379–3392, doi: . <div id="Kravitz--2017"></div> Kravitz, B. et al., 2017: First Simulations of Designing Stratospheric Sulfate Aerosol Geoengineering to Meet Multiple Simultaneous Climate Objectives. ''Journal of Geophysical Research: Atmospheres'' , '''122(23)''' , 12616–12634, doi: . <div id="Kravitz--2018"></div> Kravitz, B. et al., 2018: The climate effects of increasing ocean albedo: an idealized representation of solar geoengineering. ''Atmospheric Chemistry and Physics'' , '''18(17)''' , 13097–13113, doi: . <div id="Kravitz--2019"></div> Kravitz, B. et al., 2019: Comparing Surface and Stratospheric Impacts of Geoengineering With Different SO <sub>2</sub> injection Strategies. ''Journal of Geophysical Research: Atmospheres'' , '''124(14)''' , 7900–7918, doi: . <div id="Kravitz--2021"></div> Kravitz, B. et al., 2021: Comparing different generations of idealized solar geoengineering simulations in the Geoengineering Model Intercomparison Project (GeoMIP). ''Atmospheric Chemistry and Physics'' , '''21(6)''' , 4231–4247, doi: . <div id="Krishnamohan--2019"></div> Krishnamohan, K.-P.S.-P., G. Bala, L. Cao, L. Duan, and K. Caldeira, 2019: Climate system response to stratospheric sulfate aerosols: sensitivity to altitude of aerosol layer. ''Earth System Dynamics'' , '''10(4)''' , 885–900, doi: . <div id="Krishnamohan--2020"></div> Krishnamohan, K.-P.S.-P., G. Bala, L. Cao, L. Duan, and K. Caldeira, 2020: The Climatic Effects of Hygroscopic Growth of Sulfate Aerosols in the Stratosphere. ''Earth’s Future'' , '''8(2)''' , e2019EF001326, doi: . <div id="Krishnan--2016"></div> Krishnan, R. et al., 2016: Deciphering the desiccation trend of the South Asian monsoon hydroclimate in a warming world. ''Climate Dynamics'' , '''47(3)''' , 1007–1027, doi: . <div id="Kristjánsson--2015"></div> Kristjánsson, J.E., H. Muri, and H. Schmidt, 2015: The hydrological cycle response to cirrus cloud thinning. ''Geophysical Research Letters'' , '''42(24)''' , 10807–10815, doi: . <div id="Kröger--2018"></div> Kröger, J. et al., 2018: Full-field initialized decadal predictions with the MPI Earth system model: an initial shock in the North Atlantic. ''Climate Dynamics'' , '''51''' , 2593–2608, doi: . <div id="Kröner--2017"></div> Kröner, N. et al., 2017: Separating climate change signals into thermodynamic, lapse-rate and circulation effects: theory and application to the European summer climate. ''Climate Dynamics'' , '''48(9–10)''' , 3425–3440, doi: . <div id="Kruschke--2016"></div> Kruschke, T. et al., 2016: Probabilistic evaluation of decadal prediction skill regarding Northern Hemisphere winter storms. ''Meteorologische Zeitschrift'' , '''25(6)''' , 721–738, doi: . <div id="Kwiatkowski--2020"></div> Kwiatkowski, L. et al., 2020: Twenty-first century ocean warming, acidification, deoxygenation, and upper-ocean nutrient and primary production decline from CMIP6 model projections. ''Biogeosciences'' , '''17(13)''' , 3439–3470, doi: . <div id="Lambert--2007"></div> Lambert, F.H. and J.C.H. Chiang, 2007: Control of land–ocean temperature contrast by ocean heat uptake. ''Geophysical Research Letters'' , '''34(13)''' , L13704, doi: . <div id="Lambert--2009"></div> Lambert, F.H. and M.R. Allen, 2009: Are changes in global precipitation constrained by the tropospheric energy budget? ''Journal of Climate'' , '''22(3)''' , 499–517, doi: . <div id="Lambert--2011"></div> Lambert, F.H., M.J. Webb, and M.M. Joshi, 2011: The Relationship between Land–Ocean Surface Temperature Contrast and Radiative Forcing. ''Journal of Climate'' , '''24(13)''' , 3239–3256, doi: . <div id="Lambert--2017"></div> Lambert, F.H., A.J. Ferraro, and R. Chadwick, 2017: Land–Ocean Shifts in Tropical Precipitation Linked to Surface Temperature and Humidity Change. ''Journal of Climate'' , '''30(12)''' , 4527–4545, doi: . <div id="Langehaug--2017"></div> Langehaug, H.R., D. Matei, T. Eldevik, K. Lohmann, and Y. Gao, 2017: On model differences and skill in predicting sea surface temperature in the Nordic and Barents Seas. ''Climate Dynamics'' , '''48(3–4)''' , 913–933, doi: . <div id="Langenbrunner--2015"></div> Langenbrunner, B., J.D. Neelin, B.R. Lintner, and B.T. Anderson, 2015: Patterns of Precipitation Change and Climatological Uncertainty among CMIP5 Models, with a Focus on the Midlatitude Pacific Storm Track. ''Journal of Climate'' , '''28(19)''' , 7857–7872, doi: . <div id="Latham--2013"></div> Latham, J., J. Kleypas, R. Hauser, B. Parkes, and A. Gadian, 2013: Can marine cloud brightening reduce coral bleaching? ''Atmospheric Science Letters'' , '''14(4)''' , 214–219, doi: . <div id="Latham--2012"></div> Latham, J. et al., 2012: Marine cloud brightening. ''Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences'' , '''370(1974)''' , 4217–4262, doi: . <div id="Latham--2014"></div> Latham, J. et al., 2014: Marine cloud brightening: regional applications. ''Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences'' , '''372(2031)''' , 20140053, doi: . <div id="Lawrence--2018"></div> Lawrence, M.G. et al., 2018: Evaluating climate geoengineering proposals in the context of the Paris Agreement temperature goals. ''Nature Communications'' , '''9(1)''' , 3734, doi: . <div id="Leduc--2015"></div> Leduc, M., H.D. Matthews, and R. De Elía, 2015: Quantifying the limits of a linear temperature response to cumulative CO <sub>2</sub> emissions. ''Journal of Climate'' , '''28(24)''' , 9955–9968, doi: . <div id="Leduc--2016"></div> Leduc, M., H.D. Matthews, and R. de Elía, 2016: Regional estimates of the transient climate response to cumulative CO <sub>2</sub> emissions. ''Nature Climate Change'' , '''6(5)''' , 474–478, doi: . <div id="Lee--2017"></div> Lee, D.Y. and J.-B. Ahn, 2017: Future change in the frequency and intensity of wintertime North Pacific blocking in CMIP5 models. ''International Journal of Climatology'' , '''37(5)''' , 2765–2781, doi: . <div id="Lee--2017"></div> Lee, H.J. et al., 2017: Impact of Poleward Moisture Transport from the North Pacific on the Acceleration of Sea Ice Loss in the Arctic since 2002. ''Journal of Climate'' , '''30(17)''' , 6757–6769, doi: . <div id="Lee--2014"></div> Lee, J.Y. and B. Wang, 2014: Future change of global monsoon in the CMIP5. ''Climate Dynamics'' , '''42(1–2)''' , 101–119, doi: . <div id="Lee--2011"></div> Lee, S., T. Gong, N. Johnson, S.B. Feldstein, and D. Pollard, 2011: On the Possible Link between Tropical Convection and the Northern Hemisphere Arctic Surface Air Temperature Change between 1958 and 2001. ''Journal of Climate'' , '''24(16)''' , 4350–4367, doi: . <div id="Lee--2020"></div> Lee, W., D. MacMartin, D. Visioni, and B. Kravitz, 2020: Expanding the design space of stratospheric aerosol geoengineering to include precipitation-based objectives and explore trade-offs. ''Earth System Dynamics'' , '''11(4)''' , 1051–1072, doi: . <div id="Legrande--2016"></div> Legrande, A.N., K. Tsigaridis, and S.E. Bauer, 2016: Role of atmospheric chemistry in the climate impacts of stratospheric volcanic injections. ''Nature Geoscience'' , '''9(9)''' , 652–655, doi: . <div id="Lehmann--2014"></div> Lehmann, J., D. Coumou, K. Frieler, A. Eliseev, and A. Levermann, 2014: Future changes in extratropical storm tracks and baroclinicity under climate change. ''Environmental Research Letters'' , '''9(8)''' , 084002, doi: . <div id="Lehner--2017"></div> Lehner, F., C. Deser, and L. Terray, 2017: Toward a new estimate of “Time of Emergence” of anthropogenic warming: Insights from dynamical adjustment and a large initial-condition model ensemble. ''Journal of Climate'' , '''30(19)''' , 7739–7756, doi: . <div id="Lehner--2020"></div> Lehner, F. et al., 2020: Partitioning climate projection uncertainty with multiple large ensembles and CMIP5/6. ''Earth System Dynamics'' , '''11(2)''' , 491–508, doi: . <div id="Lemordant--2018"></div> Lemordant, L., P. Gentine, A.S. Swann, B.I. Cook, and J. Scheff, 2018: Critical impact of vegetation physiology on the continental hydrologic cycle in response to increasing CO <sub>2</sub> . ''Proceedings of the National Academy of Sciences'' , '''115(16)''' , 4093–4098, doi: . <div id="Lenderink--2014"></div> Lenderink, G. et al., 2014: Preparing local climate change scenarios for the Netherlands using resampling of climate model output. ''Environmental Research Letters'' , '''9(11)''' , 115008, doi: . <div id="Levy--2013"></div> Levy, H. et al., 2013: The roles of aerosol direct and indirect effects in past and future climate change. ''Journal of Geophysical Research: Atmospheres'' , '''118(10)''' , 4521–4532, doi: . <div id="Li--2013"></div> Li, C., J.-S. von Storch, and J. Marotzke, 2013: Deep-ocean heat uptake and equilibrium climate response. ''Climate Dynamics'' , '''40(5–6)''' , 1071–1086, doi: . <div id="Li--2018"></div> Li, C. et al., 2018: Midlatitude atmospheric circulation responses under 1.5 and 2.0°C warming and implications for regional impacts. ''Earth System Dynamics'' , '''9(2)''' , 359–382, doi: . <div id="Li--2016"></div> Li, G., S.-P. Xie, and Y. Du, 2016: A Robust but Spurious Pattern of Climate Change in Model Projections over the Tropical Indian Ocean. ''Journal of Climate'' , '''29(15)''' , 5589–5608, doi: . <div id="Li--2016"></div> Li, H., T. Ilyina, W.A. Müller, and F. Sienz, 2016: Decadal predictions of the North Atlantic CO <sub>2</sub> uptake. ''Nature Communications'' , '''7''' , 10.1038/ncomms11076, doi: . <div id="Li--2019"></div> Li, H., T. Ilyina, W.A. Müller, and P. Landschützer, 2019: Predicting the variable ocean carbon sink. ''Science Advances'' , '''5(4)''' , eaav6471, doi: . <div id="Li--2003"></div> Li, J. and J.X.L. Wang, 2003: A modified zonal index and its physical sense. ''Geophysical Research Letters'' , '''30(12)''' , 1632, doi: . <div id="Li--2014"></div> Li, M., T. Woollings, K. Hodges, and G. Masato, 2014: Extratropical cyclones in a warmer, moister climate: A recent Atlantic analogue. ''Geophysical Research Letters'' , '''41(23)''' , 8594–8601, doi: . <div id="Li--2012"></div> Li, W., L. Li, M. Ting, and Y. [[#Liu--2012|Liu, 2012]] : Intensification of Northern Hemisphere subtropical highs in a warming climate. ''Nature Geoscience'' , '''5(11)''' , 830–834, doi: . <div id="Liang--2020"></div> Liang, Y., N.P. Gillett, and A.H. Monahan, 2020: Climate Model Projections of 21st Century Global Warming Constrained Using the Observed Warming Trend. ''Geophysical Research Letters'' , '''47(12)''' , e2019GL086757, doi: . <div id="Liguori--2019"></div> Liguori, G. and E. Di Lorenzo, 2019: Separating the North and South Pacific Meridional Modes Contributions to ENSO and Tropical Decadal Variability. ''Geophysical Research Letters'' , '''46(2)''' , 906–915, doi: . <div id="Lipat--2018"></div> Lipat, B.R., A. Voigt, G. Tselioudis, and L.M. Polvani, 2018: Model uncertainty in cloud–circulation coupling, and cloud-radiative response to increasing CO <sub>2</sub> , linked to biases in climatological circulation. ''Journal of Climate'' , '''31(24)''' , 10013–10020, doi: . <div id="Liptak--2017"></div> Liptak, J., G. Keppel-Aleks, and K. Lindsay, 2017: Drivers of multi-century trends in the atmospheric CO <sub>2</sub> mean annual cycle in a prognostic ESM. ''Biogeosciences'' , '''14(6)''' , 1383–1401, doi: . <div id="Liu--2018"></div> Liu, F. et al., 2018: How Do Tropical, Northern Hemispheric, and Southern Hemispheric Volcanic Eruptions Affect ENSO Under Different Initial Ocean Conditions? ''Geophysical Research Letters'' , '''45(23)''' , 13,041–13,049, doi: . <div id="Liu--2018"></div> Liu, L. et al., 2018: A PDRMIP Multimodel Study on the Impacts of Regional Aerosol Forcings on Global and Regional Precipitation. ''Journal of Climate'' , '''31(11)''' , 4429–4447, doi: . <div id="Liu--2017"></div> Liu, W., S.-P. Xie, Z. Liu, and J. Zhu, 2017: Overlooked possibility of a collapsed Atlantic Meridional Overturning Circulation in warming climate. ''Science Advances'' , '''3(1)''' , e1601666, doi: . <div id="Liu--2018"></div> Liu, W., J. Lu, S.-P. Xie, and A. Fedorov, 2018: Southern Ocean Heat Uptake, Redistribution, and Storage in a Warming Climate: The Role of Meridional Overturning Circulation. ''Journal of Climate'' , '''31(12)''' , 4727–4743, doi: . <div id="Liu--2018"></div> Liu, Y. et al., 2018: Climate response to the meltwater runoff from Greenland ice sheet: evolving sensitivity to discharging locations. ''Climate Dynamics'' , '''51(5–6)''' , 1733–1751, doi: . <div id="Liu--2012"></div> Liu, Z., 2012: Dynamics of Interdecadal Climate Variability: A Historical Perspective. ''Journal of Climate'' , '''25(6)''' , 1963–1995, doi: . <div id="Liu--2018"></div> Liu, Z. and E. Di Lorenzo, 2018: Mechanisms and Predictability of Pacific Decadal Variability. ''Current Climate Change Reports'' , '''4(2)''' , 128–144, doi: . <div id="Lo--2016"></div> Lo, Y.T.E., A.J. Charlton-Perez, F.C. Lott, and E.J. Highwood, 2016: Detecting sulphate aerosol geoengineering with different methods. ''Scientific Reports'' , '''6''' , 1–10, doi: . <div id="Lohmann--2017"></div> Lohmann, U. and B. Gasparini, 2017: A cirrus cloud climate dial? ''Science'' , '''357(6348)''' , 248–249, doi: . <div id="Lopez--2014"></div> Lopez, A., E.B. Suckling, and L.A. Smith, 2014: Robustness of pattern scaled climate change scenarios for adaptation decision support. ''Climatic Change'' , '''122(4)''' , 555–566, doi: . <div id="Losada--2016"></div> Losada, T. and B. Rodríguez-Fonseca, 2016: Tropical atmospheric response to decadal changes in the Atlantic Equatorial Mode. ''Climate Dynamics'' , '''47(3–4)''' , 1211–1224, doi: . <div id="Lovenduski--2019"></div> Lovenduski, N.S., S.G. Yeager, K. Lindsay, and M.C. Long, 2019: Predicting near-term variability in ocean carbon uptake. ''Earth System Dynamics'' , '''10(1)''' , 45–57, doi: . <div id="Lovenduski--2016"></div> Lovenduski, N.S., G.A. McKinley, A.R. Fay, K. Lindsay, and M.C. Long, 2016: Partitioning uncertainty in ocean carbon uptake projections: Internal variability, emission scenario, and model structure. ''Global Biogeochemical Cycles'' , '''30(9)''' , 1276–1287, doi: . <div id="Lübbecke--2018"></div> Lübbecke, J.F. et al., 2018: Equatorial Atlantic variability-Modes, mechanisms, and global teleconnections. ''WIREs Climate Change'' , '''9(4)''' , e527, doi: . <div id="Luo--2018"></div> Luo, D., X. Chen, A. Dai, and I. Simmonds, 2018: Changes in Atmospheric Blocking Circulations Linked with Winter Arctic Warming: A New Perspective. ''Journal of Climate'' , '''31(18)''' , 7661–7678, doi: . <div id="MacCracken--2016"></div> MacCracken, M.C., 2016: The rationale for accelerating regionally focused climate intervention research. ''Earth’s Future'' , '''4(12)''' , 649–657, doi: . <div id="MacCracken--2013"></div> MacCracken, M.C., H.J. Shin, K. Caldeira, and G.A. Ban-Weiss, 2013: Climate response to imposed solar radiation reductions in high latitudes. ''Earth System Dynamics'' , '''4(2)''' , 301–315, doi: . <div id="MacDougall--2013"></div> MacDougall, A.H., 2013: Reversing climate warming by artificial atmospheric carbon-dioxide removal: Can a Holocene-like climate be restored? ''Geophysical Research Letters'' , '''40(20)''' , 5480–5485. <div id="MacDougall--2020"></div> MacDougall, A.H. et al., 2020: Is there warming in the pipeline? A multi-model analysis of the Zero Emissions Commitment from CO <sub>2</sub> . ''Biogeosciences'' , '''17(11)''' , 2987–3016, doi: . <div id="MacLachlan--2015"></div> MacLachlan, C. et al., 2015: Global Seasonal forecast system version 5 (GloSea5): a high-resolution seasonal forecast system. ''Quarterly Journal of the Royal Meteorological Society'' , '''141(689)''' , 1072–1084, doi: . <div id="MacMartin--2014"></div> MacMartin, D.G., K. Caldeira, and D.W. Keith, 2014: Solar geoengineering to limit the rate of temperature change. ''Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences'' , '''372(2031)''' , 20140134, doi: . <div id="MacMartin--2018"></div> MacMartin, D.G., K.L. Ricke, and D.W. Keith, 2018: Solar geoengineering as part of an overall strategy for meeting the 1.5°C Paris target. ''Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences'' , '''376(2119)''' , 20160454, doi: . <div id="MacMartin--2017"></div> MacMartin, D.G. et al., 2017: The Climate Response to Stratospheric Aerosol Geoengineering Can Be Tailored Using Multiple Injection Locations. ''Journal of Geophysical Research: Atmospheres'' , '''122(23)''' , 12574–12590, doi: . <div id="MacMartin--2019"></div> MacMartin, D.G. et al., 2019: Timescale for Detecting the Climate Response to Stratospheric Aerosol Geoengineering. ''Journal of Geophysical Research: Atmospheres'' , '''124(3)''' , 1233–1247, doi: . <div id="Madsen--2017"></div> Madsen, M.S., P.L. Langen, F. Boberg, and J.H. Christensen, 2017: Inflated Uncertainty in Multimodel-Based Regional Climate Projections. ''Geophysical Research Letters'' , '''44(22)''' , 11606–11613, doi: . <div id="Magnusson--2013"></div> Magnusson, L., M. Alonso-Balmaseda, S. Corti, F. Molteni, and T. Stockdale, 2013: Evaluation of forecast strategies for seasonal and decadal forecasts in presence of systematic model errors. ''Climate Dynamics'' , '''41(9–10)''' , 2393–2409, doi: . <div id="Maher--2020"></div> Maher, N., F. Lehner, and J. Marotzke, 2020: Quantifying the role of internal variability in the temperature we expect to observe in the coming decades. ''Environmental Research Letters'' , '''15(5)''' , 054014, doi: . <div id="Maher--2021"></div> Maher, N., S.B. Power, and J. Marotzke, 2021: More accurate quantification of model-to-model agreement in externally forced climatic responses over the coming century. ''Nature Communications'' , '''12(1)''' , 788, doi: . <div id="Maher--2015"></div> Maher, N., S. McGregor, M.H. England, and A. Gupta, 2015: Effects of volcanism on tropical variability. ''Geophysical Research Letters'' , '''42(14)''' , 6024–6033, doi: . <div id="Maher--2018"></div> Maher, N., D. Matei, S. Milinski, and J. Marotzke, 2018: ENSO Change in Climate Projections: Forced Response or Internal Variability? ''Geophysical Research Letters'' , '''45(20)''' , 11390–11398, doi: . <div id="Maher--2019"></div> Maher, N. et al., 2019: The Max Planck Institute Grand Ensemble: Enabling the Exploration of Climate System Variability. ''Journal of Advances in Modeling Earth Systems'' , '''11(7)''' , 2050–2069, doi: . <div id="Mahlstein--2011"></div> Mahlstein, I. and R. Knutti, 2011: Ocean Heat Transport as a Cause for Model Uncertainty in Projected Arctic Warming. ''Journal of Climate'' , '''24(5)''' , 1451–1460, doi: . <div id="Mahowald--2017"></div> Mahowald, N.M. et al., 2017: Interactions between land use change and carbon cycle feedbacks. ''Global Biogeochemical Cycles'' , '''31(1)''' , 96–113, doi: . <div id="Man--2014"></div> Man, W., T. Zhou, and J.H. Jungclaus, 2014: Effects of Large Volcanic Eruptions on Global Summer Climate and East Asian Monsoon Changes during the Last Millennium: Analysis of MPI-ESM Simulations. ''Journal of Climate'' , '''27(19)''' , 7394–7409, doi: . <div id="Man--2021"></div> Man, W. et al., 2021: Potential Influences of Volcanic Eruptions on Future Global Land Monsoon Precipitation Changes. ''Earth’s Future'' , '''9(3)''' , e2020EF001803, doi: . <div id="Manabe--1975"></div> Manabe, S. and R.T. Wetherald, 1975: The Effects of Doubling the CO <sub>2</sub> concentration on the climate of a General Circulation Model. ''Journal of the Atmospheric Sciences'' , '''32(1)''' , 3–15, doi: . <div id="Manabe--1980"></div> Manabe, S. and R.J. Stouffer, 1980: Sensitivity of a global climate model to an increase of CO <sub>2</sub> concentration in the atmosphere. ''Journal of Geophysical Research: Oceans'' , '''85(C10)''' , 5529, doi: . <div id="Manabe--1980"></div> Manabe, S. and R.T. Wetherald, 1980: On the Distribution of Climate Change Resulting from an Increase in CO <sub>2</sub> Content of the Atmosphere. ''Journal of the Atmospheric Sciences'' , '''37(1)''' , 99–118, doi: . <div id="Manabe--1991"></div> Manabe, S., R.J. Stouffer, M.J. Spelman, and K. Bryan, 1991: Transient Responses of a Coupled Ocean–Atmosphere Model to Gradual Changes of Atmospheric CO <sub>2</sub> . Part I. Annual Mean Response. ''Journal of Climate'' , '''4(8)''' , 785–818, doi: . <div id="Mann--2020"></div> Mann, M.E., B.A. Steinman, and S.K. Miller, 2020: Absence of internal multidecadal and interdecadal oscillations in climate model simulations. ''Nature Communications'' , '''11(1)''' , 49, doi: . <div id="Mann--2021"></div> Mann, M.E., B.A. Steinman, D.J. Brouillette, and S.K. Miller, 2021: Multidecadal climate oscillations during the past millennium driven by volcanic forcing. ''Science'' , '''371(6533)''' , 1014–1019, doi: . <div id="Mantua--1997"></div> Mantua, N.J., S.R. Hare, Y. Zhang, J.M. Wallace, and R.C. Francis, 1997: A Pacific Interdecadal Climate Oscillation with Impacts on Salmon Production. ''Bulletin of the American Meteorological Society'' , '''78(6)''' , 1069–1079, doi: . <div id="Manzini--2014"></div> Manzini, E. et al., 2014: Northern winter climate change: Assessment of uncertainty in CMIP5 projections related to stratosphere–troposphere coupling. ''Journal of Geophysical Research: Atmospheres'' , '''119(13)''' , 7979–7998, doi: . <div id="Marini--2016"></div> Marini, C., I. Polkova, A. Köhl, and D. Stammer, 2016: A Comparison of Two Ensemble Generation Methods Using Oceanic Singular Vectors and Atmospheric Lagged Initialization for Decadal Climate Prediction. ''Monthly Weather Review'' , '''144(7)''' , 2719–2738, doi: . <div id="Marotzke--2019"></div> Marotzke, J., 2019: Quantifying the irreducible uncertainty in near-term climate projections. ''WIREs Climate Change'' , '''10(1)''' , e563, doi: . <div id="Marotzke--2015"></div> Marotzke, J. and P.M. Forster, 2015: Forcing, feedback and internal variability in global temperature trends. ''Nature'' , '''517(7536)''' , 565–570, doi: . <div id="Marotzke--2016"></div> Marotzke, J. et al., 2016: MiKlip: A national research project on decadal climate prediction. ''Bulletin of the American Meteorological Society'' , '''97(12)''' , 2379–2394, doi: . <div id="Marshall--2003"></div> Marshall, G.J., 2003: Trends in the Southern Annular Mode from Observations and Reanalyses. ''Journal of Climate'' , '''16(24)''' , 4134–4143, doi: . <div id="Marshall--2014"></div> Marshall, J. et al., 2014: The ocean’s role in polar climate change: asymmetric Arctic and Antarctic responses to greenhouse gas and ozone forcing. ''Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences'' , '''372(2019)''' , 20130040, doi: . <div id="Marshall--2015"></div> Marshall, J. et al., 2015: The ocean’s role in the transient response of climate to abrupt greenhouse gas forcing. ''Climate Dynamics'' , '''44(7–8)''' , 2287–2299, doi: . <div id="Marshall--2019"></div> Marshall, L.R. et al., 2019: Exploring How Eruption Source Parameters Affect Volcanic Radiative Forcing Using Statistical Emulation. ''Journal of Geophysical Research: Atmospheres'' , '''124(2)''' , 964–985, doi: . <div id="Marshall--2020"></div> Marshall, L.R. et al., 2020: Large Variations in Volcanic Aerosol Forcing Efficiency Due to Eruption Source Parameters and Rapid Adjustments. ''Geophysical Research Letters'' , '''47(19)''' , e2020GL090241, doi: . <div id="Martin--2014a"></div> Martin, E.R. and C. Thorncroft, 2014a: Sahel rainfall in multimodel CMIP5 decadal hindcasts. ''Geophysical Research Letters'' , '''41(6)''' , 2169–2175, doi: . <div id="Martin--2014b"></div> Martin, E.R. and C.D. Thorncroft, 2014b: The impact of the AMO on the West African monsoon annual cycle. ''Quarterly Journal of the Royal Meteorological Society'' , '''140(678)''' , 31–46, doi: . <div id="Martín-Rey--2014"></div> Martín-Rey, M., B. Rodríguez-Fonseca, I. Polo, and F. Kucharski, 2014: On the Atlantic–Pacific Niños connection: a multidecadal modulated mode. ''Climate Dynamics'' , '''43(11)''' , 3163–3178, doi: . <div id="Martín-Rey--2017"></div> Martín-Rey, M., I. Polo, B. Rodríguez-Fonseca, T. Losada, and A. Lazar, 2017: Is There Evidence of Changes in Tropical Atlantic Variability Modes under AMO Phases in the Observational Record? ''Journal of Climate'' , '''41(7)''' , 3071–3089, doi: . <div id="Marvel--2016"></div> Marvel, K., G.A. Schmidt, R.L. Miller, and L.S. Nazarenko, 2016: Implications for climate sensitivity from the response to individual forcings. ''Nature Climate Change'' , '''6(4)''' , 386–389, doi: . <div id="Masato--2013"></div> Masato, G., B.J. Hoskins, and T. Woollings, 2013: Winter and Summer Northern Hemisphere Blocking in CMIP5 Models. ''Journal of Climate'' , '''26(18)''' , 7044–7059, doi: . <div id="Massonnet--2019"></div> Massonnet, F., 2019: Climate Models as Guidance for the Design of Observing Systems: the Case of Polar Climate and Sea Ice Prediction. ''Current Climate Change Reports'' , '''5(4)''' , 334–344, doi: . <div id="Massonnet--2016"></div> Massonnet, F., O. Bellprat, V. Guemas, and F.J. Doblas-Reyes, 2016: Using climate models to estimate the quality of global observational data sets. ''Science'' , '''354(6311)''' , 452–455, doi: . <div id="Matsueda--2017"></div> Matsueda, M. and H. Endo, 2017: The robustness of future changes in Northern Hemisphere blocking: A large ensemble projection with multiple sea surface temperature patterns. ''Geophysical Research Letters'' , '''44(10)''' , 5158–5166, doi: . <div id="Matthes--2017"></div> Matthes, K. et al., 2017: Solar forcing for CMIP6 (v3.2). ''Geoscientific Model Development'' , '''10(6)''' , 2247–2302, doi: . <div id="Matthews--2010"></div> Matthews, H.D., 2010: Can carbon cycle geoengineering be a useful complement to ambitious climate mitigation? ''Carbon Management'' , '''1(1)''' , 135–144, doi: . <div id="Matthews--2007"></div> Matthews, H.D. and K. Caldeira, 2007: Transient climate carbon simulations of planetary geoengineering. ''Proceedings of the National Academy of Sciences'' , '''104(24)''' , 9949–9954, doi: . <div id="Matthews--2008"></div> Matthews, H.D. and K. Caldeira, 2008: Stabilizing climate requires near-zero emissions. ''Geophysical Research Letters'' , '''35(4)''' , L04705, doi: . <div id="Maycock--2016"></div> Maycock, A.C., 2016: The contribution of ozone to future stratospheric temperature trends. ''Geophysical Research Letters'' , '''43(9)''' , 4609–4616, doi: . <div id="McCusker--2015"></div> McCusker, K.E., D.S. Battisti, and C.M. Bitz, 2015: Inability of stratospheric sulfate aerosol injections to preserve the West Antarctic Ice Sheet. ''Geophysical Research Letters'' , '''42(12)''' , 4989–4997, doi: . <div id="McCusker--2016"></div> McCusker, K.E., J.C. Fyfe, and M. Sigmond, 2016: Twenty-five winters of unexpected Eurasian cooling unlikely due to Arctic sea-ice loss. ''Nature Geoscience'' , '''9(11)''' , 838–842, doi: . <div id="McCusker--2014"></div> McCusker, K.E., K.C. Armour, C.M. Bitz, and D.S. Battisti, 2014: Rapid and extensive warming following cessation of solar radiation management. ''Environmental Research Letters'' , '''9(2)''' , 024005, doi: . <div id="McCusker--2017"></div> McCusker, K.E. et al., 2017: Remarkable separability of circulation response to Arctic sea ice loss and greenhouse gas forcing. ''Geophysical Research Letters'' , '''44(15)''' , 7955–7964, doi: . <div id="McGregor--2015"></div> McGregor, H. et al., 2015: Robust global ocean cooling trend for the pre-industrial Common Era. ''Nature Geoscience'' , '''8(9)''' , 671–677, doi: . <div id="McGregor--2010"></div> McGregor, S., A. Timmermann, and O. Timm, 2010: A unified proxy for ENSO and PDO variability since 1650. ''Climate of the Past'' , '''6(1)''' , 1–17, doi: . <div id="McKenna--2018"></div> McKenna, C.M., T.J. Bracegirdle, E.F. Shuckburgh, P.H. Haynes, and M.M. Joshi, 2018: Arctic Sea Ice Loss in Different Regions Leads to Contrasting Northern Hemisphere Impacts. ''Geophysical Research Letters'' , '''45(2)''' , 945–954, doi: . <div id="McKenna--2021"></div> McKenna, C.M., A.C. Maycock, P.M. Forster, C.J. Smith, and K.B. Tokarska, 2021: Stringent mitigation substantially reduces risk of unprecedented near-term warming rates. ''Nature Climate Change'' , '''11(2)''' , 126–131, doi: . <div id="McKinnon--2017"></div> McKinnon, K.A., A. Poppick, E. Dunn-Sigouin, and C. Deser, 2017: An “Observational Large Ensemble” to Compare Observed and Modeled Temperature Trend Uncertainty due to Internal Variability. ''Journal of Climate'' , '''30(19)''' , 7585–7598, doi: . <div id="McSweeney--2013"></div> McSweeney, C.F. and R.G. Jones, 2013: No consensus on consensus: the challenge of finding a universal approach to measuring and mapping ensemble consistency in GCM projections. ''Climatic Change'' , '''119(3–4)''' , 617–629, doi: . <div id="Mearns--1997"></div> Mearns, L.O., C. Rosenzweig, and R. Goldberg, 1997: Mean and variance change in climate scenarios: Methods, agricultural applications, and measures of uncertainty. ''Climatic Change'' , '''35(4)''' , 367–396, doi: . <div id="Meccia--2020"></div> Meccia, V.L., F. Fabiano, P. Davini, and S. Corti, 2020: Stochastic Parameterizations and the Climate Response to External Forcing: An Experiment With EC-Earth. ''Geophysical Research Letters'' , '''47(3)''' , e2019GL085951, doi: . <div id="Meehl--2012"></div> Meehl, G.A. and H. Teng, 2012: Case studies for initialized decadal hindcasts and predictions for the Pacific region. ''Geophysical Research Letters'' , '''39(22)''' , L22705, doi: . <div id="Meehl--2016"></div> Meehl, G.A., A. Hu, and H. Teng, 2016: Initialized decadal prediction for transition to positive phase of the Interdecadal Pacific Oscillation. ''Nature Communications'' , '''7(1)''' , 11718, doi: . <div id="Meehl--2015"></div> Meehl, G.A., H. Teng, N. Maher, and M.H. England, 2015: Effects of the Mount Pinatubo eruption on decadal climate prediction skill of Pacific sea surface temperatures. ''Geophysical Research Letters'' , '''42(24)''' , 10840–10846, doi: . <div id="Meehl--2014"></div> Meehl, G.A. et al., 2014: Decadal climate prediction an update from the trenches. ''Bulletin of the American Meteorological Society'' , '''95(2)''' , 243–267, doi: . <div id="Meehl--2020"></div> Meehl, G.A. et al., 2020: Context for interpreting equilibrium climate sensitivity and transient climate response from the CMIP6 Earth system models. ''Science Advances'' , '''6(26)''' , eaba1981, doi: . <div id="Meinshausen--2011"></div> Meinshausen, M. et al., 2011: The RCP greenhouse gas concentrations and their extensions from 1765 to 2300. ''Climatic Change'' , '''109(1–2)''' , 213–241, doi: . <div id="Meinshausen--2020"></div> Meinshausen, M. et al., 2020: The shared socio-economic pathway (SSP) greenhouse gas concentrations and their extensions to 2500. ''Geoscientific Model Development'' , '''13(8)''' , 3571–3605, doi: . <div id="Menary--2018"></div> Menary, M.B. and L. Hermanson, 2018: Limits on determining the skill of North Atlantic Ocean decadal predictions. ''Nature Communications'' , '''9(1)''' , 1694, doi: . <div id="Menary--2015"></div> Menary, M.B. et al., 2015: Exploring the impact of CMIP5 model biases on the simulation of North Atlantic decadal variability. ''Geophysical Research Letters'' , '''42(14)''' , 5926–5934, doi: . <div id="Mengis--2019"></div> Mengis, N., D.P. Keller, W. Rickels, M. Quaas, and A. Oschlies, 2019: Climate engineering-induced changes in correlations between Earth system variables – implications for appropriate indicator selection. ''Climatic Change'' , '''153(3)''' , 305–322, doi: . <div id="Merlis--2018"></div> Merlis, T.M. and M. Henry, 2018: Simple Estimates of Polar Amplification in Moist Diffusive Energy Balance Models. ''Journal of Climate'' , '''31(15)''' , 5811–5824, doi: . <div id="Michaelis--2017"></div> Michaelis, A.C., J. Willison, G.M. Lackmann, and W.A. Robinson, 2017: Changes in Winter North Atlantic Extratropical Cyclones in High-Resolution Regional Pseudo–Global Warming Simulations. ''Journal of Climate'' , '''30(17)''' , 6905–6925, doi: . <div id="Mignot--2016"></div> Mignot, J. et al., 2016: Decadal prediction skill in the ocean with surface nudging in the IPSL-CM5A-LR climate model. ''Climate Dynamics'' , '''47(3–4)''' , 1225–1246, doi: . <div id="Milinski--2020"></div> Milinski, S., N. Maher, and D. Olonscheck, 2020: How large does a large ensemble need to be? ''Earth System Dynamics'' , '''11(4)''' , 885–901, doi: . <div id="Millar--2017"></div> Millar, R.J. et al., 2017: Emission budgets and pathways consistent with limiting warming to 1.5°C. ''Nature Geoscience'' , '''10(10)''' , 741–748, doi: . <div id="Millar--2018a"></div> Millar, R.J. et al., 2018a: Author Correction: Emission budgets and pathways consistent with limiting warming to 1.5°C. ''Nature Geoscience'' , '''11(6)''' , 454–455, doi: . <div id="Millar--2018b"></div> Millar, R.J. et al., 2018b: Reply to ’Interpretations of the Paris climate target’. ''Nature Geoscience'' , '''11(4)''' , 222, doi: . <div id="Miller--2012"></div> Miller, G.H. et al., 2012: Abrupt onset of the Little Ice Age triggered by volcanism and sustained by sea-ice/ocean feedbacks. ''Geophysical Research Letters'' , '''39(2)''' , 1–5, doi: . <div id="Mindlin--2020"></div> Mindlin, J. et al., 2020: Storyline description of Southern Hemisphere midlatitude circulation and precipitation response to greenhouse gas forcing. ''Climate Dynamics'' , '''54(9–10)''' , 4399–4421, doi: . <div id="Minx--2018"></div> Minx, J.C. et al., 2018: Negative emissions – Part 1: Research landscape and synthesis. ''Environmental Research Letters'' , '''13(6)''' , 063001, doi: . <div id="Mitchell--2017"></div> Mitchell, D. et al., 2017: Half a degree additional warming, prognosis and projected impacts (HAPPI): background and experimental design. ''Geoscientific Model Development'' , '''10(2)''' , 571–583, doi: . <div id="Mitchell--2009"></div> Mitchell, D.L. and W. Finnegan, 2009: Modification of cirrus clouds to reduce global warming. ''Environmental Research Letters'' , '''4(4)''' , 045102, doi: . <div id="Mitchell--2003"></div> Mitchell, T.D., 2003: Pattern Scaling: An Examination of the Accuracy of the Technique for Describing Future Climates. ''Climatic Change'' , '''60(3)''' , 217–242, doi: . <div id="Mizuta--2014"></div> Mizuta, R. et al., 2014: Classification of CMIP5 Future Climate Responses by the Tropical Sea Surface Temperature Changes. ''SOLA'' , '''10''' , 167–171, doi: . <div id="Mochizuki--2010"></div> Mochizuki, T. et al., 2010: Pacific decadal oscillation hindcasts relevant to near-term climate prediction. ''Proceedings of the National Academy of Sciences'' , '''107(5)''' , 1833–1837, doi: . <div id="Mochizuki--2012"></div> Mochizuki, T. et al., 2012: Decadal Prediction Using a Recent Series of MIROC Global Climate Models. ''Journal of the Meteorological Society of Japan'' , '''90A''' , 373–383, doi: . <div id="Modak--2019"></div> Modak, A. and G. Bala, 2019: Efficacy of black carbon aerosols: the role of shortwave cloud feedback. ''Environmental Research Letters'' , '''14(8)''' , 084029, doi: . <div id="Modak--2016"></div> Modak, A., G. Bala, L. Cao, and K. Caldeira, 2016: Why must a solar forcing be larger than a CO <sub>2</sub> forcing to cause the same global mean surface temperature change? ''Environmental Research Letters'' , '''11(4)''' , 044013, doi: . <div id="Modak--2018"></div> Modak, A., G. Bala, K. Caldeira, and L. Cao, 2018: Does shortwave absorption by methane influence its effectiveness? ''Climate Dynamics'' , '''51(9–10)''' , 3653–3672, doi: . <div id="Mohino--2015"></div> Mohino, E. and T. Losada, 2015: Impacts of the Atlantic Equatorial Mode in a warmer climate. ''Climate Dynamics'' , '''45(7–8)''' , 2255–2271, doi: . <div id="Mohino--2016"></div> Mohino, E., N. Keenlyside, and H. Pohlmann, 2016: Decadal prediction of Sahel rainfall: where does the skill (or lack thereof) come from? ''Climate Dynamics'' , '''47(11)''' , 3593–3612, doi: . <div id="Mohino--2019"></div> Mohino, E., B. Rodríguez-Fonseca, C.R. Mechoso, T. Losada, and I. Polo, 2019: Relationships among Intermodel Spread and Biases in Tropical Atlantic Sea Surface Temperatures. ''Journal of Climate'' , '''32(12)''' , 3615–3635, doi: . <div id="Mohtadi--2016"></div> Mohtadi, M., M. Prange, and S. Steinke, 2016: Palaeoclimatic insights into forcing and response of monsoon rainfall. ''Nature'' , '''533(7602)''' , 191–199, doi: . <div id="Monerie--2018"></div> Monerie, P.-A., J. Robson, B. Dong, and N. Dunstone, 2018: A role of the Atlantic Ocean in predicting summer surface air temperature over North East Asia? ''Climate Dynamics'' , '''51(1)''' , 473–491, doi: . <div id="Monerie--2017"></div> Monerie, P.-A. et al., 2017: Decadal prediction skill using a high-resolution climate model. ''Climate Dynamics'' , '''49(9–10)''' , 3527–3550, doi: . <div id="Moore--2017"></div> Moore, G.W.K., J. Halfar, H. Majeed, W. Adey, and A. Kronz, 2017: Amplification of the Atlantic Multidecadal Oscillation associated with the onset of the industrial-era warming. ''Scientific Reports'' , '''7(1)''' , 40861, doi: . <div id="Moore--2018"></div> Moore, J.C., R. Gladstone, T. Zwinger, and M. Wolovick, 2018: Geoengineer polar glaciers to slow sea-level rise. ''Nature'' , '''555(7696)''' , 303–305, doi: . <div id="Moore--2014"></div> Moore, J.C. et al., 2014: Arctic sea ice and atmospheric circulation under the GeoMIP G1 scenario. ''Journal of Geophysical Research: Atmospheres'' , '''119(2)''' , 567–583, doi: . <div id="Moore--2015"></div> Moore, J.C. et al., 2015: Atlantic hurricane surge response to geoengineering. ''Proceedings of the National Academy of Sciences'' , '''112(45)''' , 13794–9, doi: . <div id="Moore--2018"></div> Moore, J.K. et al., 2018: Sustained climate warming drives declining marine biological productivity. ''Science'' , '''359(6380)''' , 1139–1143, doi: . <div id="Mori--2014"></div> Mori, M., M. Watanabe, H. Shiogama, J. Inoue, and M. Kimoto, 2014: Robust Arctic sea-ice influence on the frequent Eurasian cold winters in past decades. ''Nature Geoscience'' , '''7(12)''' , 869–873, doi: . <div id="Morice--2021"></div> Morice, C.P. et al., 2021: An Updated Assessment of Near-Surface Temperature Change From 1850: The HadCRUT5 Data Set. ''Journal of Geophysical Research: Atmospheres'' , '''126(3)''' , e2019JD032361, doi: . <div id="Msadek--2014"></div> Msadek, R., G.A. Vecchi, M. Winton, and R.G. Gudgel, 2014: Importance of initial conditions in seasonal predictions of Arctic sea ice extent. ''Geophysical Research Letters'' , '''41(14)''' , 5208–5215, doi: . <div id="Müller--2012"></div> Müller, W.A. et al., 2012: Forecast skill of multi-year seasonal means in the decadal prediction system of the Max Planck Institute for Meteorology. ''Geophysical Research Letters'' , '''39(22)''' , L22707, doi: . <div id="Muri--2015"></div> Muri, H., U. Niemeier, and J.E. Kristjánsson, 2015: Tropical rainforest response to marine sky brightening climate engineering. ''Geophysical Research Letters'' , '''42(8)''' , 2951–2960, doi: . <div id="Muri--2014"></div> Muri, H., J.E. Kristjansson, T. Storelvmo, and M.A. Pfeffer, 2014: The climatic effects of modifying cirrus clouds in a climate engineering framework. ''Journal of Geophysical Research: Atmospheres'' , '''119(7)''' , 4174–4191, doi: . <div id="Muri--2018"></div> Muri, H. et al., 2018: Climate response to aerosol geoengineering: A multimethod comparison. ''Journal of Climate'' , '''31(16)''' , 6319–6340, doi: . <div id="Murphy--2004"></div> Murphy, J.M. et al., 2004: Quantification of modelling uncertainties in a large ensemble of climate change simulations. ''Nature'' , '''430(7001)''' , 768–772, doi: . <div id="Muthyala--2018"></div> Muthyala, R., G. Bala, and A. Nalam, 2018: Regional Scale Analysis of Climate Extremes in an SRM Geoengineering Simulation, Part 1: Precipitation Extremes. ''Current Science'' , '''114(05)''' , 1024–1035, doi: . <div id="Myhre--2017"></div> Myhre, G. et al., 2017: PDRMIP: A Precipitation Driver and Response Model Intercomparison Project-Protocol and Preliminary Results. ''Bulletin of the American Meteorological Society'' , '''98(6)''' , 1185–1198, doi: . <div id="Myhre--2018"></div> Myhre, G. et al., 2018: Sensible heat has significantly affected the global hydrological cycle over the historical period. ''Nature Communications'' , '''9(1)''' , 1922, doi: . <div id="Nadiga--2013"></div> Nadiga, B.T., W.R. Casper, and P.W. Jones, 2013: Ensemble-based global ocean data assimilation. ''Ocean Modelling'' , '''72''' , 210–230, doi: . <div id="Nadiga--2019"></div> Nadiga, B.T., T. Verma, W. Weijer, and N.M. Urban, 2019: Enhancing Skill of Initialized Decadal Predictions Using a Dynamic Model of Drift. ''Geophysical Research Letters'' , '''46(16)''' , 9991–9999, doi: . <div id="Najafi--2015"></div> Najafi, M.R., F.W. Zwiers, and N.P. Gillett, 2015: Attribution of Arctic temperature change to greenhouse-gas and aerosol influences. ''Nature Climate Change'' , '''5(3)''' , 246–249, doi: . <div id="Nalam--2018"></div> Nalam, A., G. Bala, and A. Modak, 2018: Effects of Arctic geoengineering on precipitation in the tropical monsoon regions. ''Climate Dynamics'' , '''50(''' '''9–10''' ''')''' , 3375–3395, doi: . <div id="Neely--2014"></div> Neely, R.R., D.R. Marsh, K.L. Smith, S.M. Davis, and L.M. Polvani, 2014: Biases in southern hemisphere climate trends induced by coarsely specifying the temporal resolution of stratospheric ozone. ''Geophysical Research Letters'' , '''41(23)''' , 8602–8610, doi: . <div id="Nemet--2018"></div> Nemet, G.F. et al., 2018: Negative emissions – Part 3: Innovation and upscaling. ''Environmental Research Letters'' , '''13(6)''' , 063003, doi: . <div id="Neukom--2019"></div> Neukom, R. et al., 2019: Consistent multidecadal variability in global temperature reconstructions and simulations over the Common Era. ''Nature Geoscience'' , '''12(8)''' , 643–649, doi: . <div id="Newhall--2018"></div> Newhall, C., S. Self, and A. Robock, 2018: Anticipating future Volcanic Explosivity Index (VEI) 7 eruptions and their chilling impacts. ''Geosphere'' , '''14(2)''' , 572–603, doi: . <div id="Newman--2016"></div> Newman, M. et al., 2016: The Pacific Decadal Oscillation, Revisited. ''Journal of Climate'' , '''29(12)''' , 4399–4427, doi: . <div id="Niederdrenk--2018"></div> Niederdrenk, A.L. and D. Notz, 2018: Arctic Sea Ice in a 1.5°C Warmer World. ''Geophysical Research Letters'' , '''45(4)''' , 1963–1971, doi: . <div id="Niemeier--2015"></div> Niemeier, U. and C. Timmreck, 2015: What is the limit of climate engineering by stratospheric injection of SO <sub>2</sub> ? ''Atmospheric Chemistry and Physics'' , '''15(16)''' , 9129–9141, doi: . <div id="Niemeier--2017"></div> Niemeier, U. and H. Schmidt, 2017: Changing transport processes in the stratosphere by radiative heating of sulfate aerosols. ''Atmospheric Chemistry and Physics'' , '''17(24)''' , 14871–14886, doi: . <div id="Niemeier--2013"></div> Niemeier, U., H. Schmidt, K. Alterskjær, and J.E. Kristjánsson, 2013: Solar irradiance reduction via climate engineering: Impact of different techniques on the energy balance and the hydrological cycle. ''Journal of Geophysical Research: Atmospheres'' , '''118(21)''' , 11905–11917, doi: . <div id="Nijsse--2020"></div> Nijsse, F.J.M.M., P.M. Cox, and M.S. Williamson, 2020: Emergent constraints on transient climate response (TCR) and equilibrium climate sensitivity (ECS) from historical warming in CMIP5 and CMIP6 models. ''Earth System Dynamics'' , '''11(3)''' , 737–750, doi: . <div id="Nohara--2015"></div> Nohara, D. et al., 2015: Examination of a climate stabilization pathway via zero-emissions using Earth system models. ''Environmental Research Letters'' , '''10(9)''' , 095005, doi: . <div id="Notz--2015"></div> Notz, D., 2015: How well must climate models agree with observations? ''Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences'' , '''373(2052)''' , 20140164, doi: . <div id="Notz--2018"></div> Notz, D. and J. Stroeve, 2018: The Trajectory Towards a Seasonally Ice-Free Arctic Ocean. ''Current Climate Change Reports'' , '''4(4)''' , 407–416, doi: . <div id="Notz--2020"></div> Notz, D. and SIMIP Community, 2020: Arctic Sea Ice in CMIP6. ''Geophysical Research Letters'' , '''47(10)''' , e2019GL086749, doi: . <div id="Notz--2016"></div> Notz, D. et al., 2016: The CMIP6 Sea-Ice Model Intercomparison Project (SIMIP): understanding sea ice through climate-model simulations. ''Geoscientific Model Development'' , '''9(9)''' , 3427–3446, doi: . <div id="NRC--2015a"></div> [[#NRC--2015a|NRC, 2015a]] : ''Climate Intervention: Carbon Dioxide Removal and Reliable Sequestration'' . National Research Council (NRC). The National Academies Press, Washington, DC, USA, 154 pp., doi: . <div id="NRC--2015b"></div> [[#NRC--2015b|NRC, 2015b]] : ''Climate Intervention: Reflecting Sunlight to Cool Earth'' . National Research Council (NRC). The National Academies Press, Washington, DC, USA, 260 pp., doi: . <div id="Nummelin--2017"></div> Nummelin, A., C. Li, and P.J. Hezel, 2017: Connecting ocean heat transport changes from the midlatitudes to the Arctic Ocean. ''Geophysical Research Letters'' , '''44''' , 1899–1908, doi: . <div id="O’Hagan--1976"></div> O’Hagan, A. and T.O.M. Leonard, 1976: Bayes estimation subject to uncertainty about parameter constraints. ''Biometrika'' , '''63(1)''' , 201–203, doi: . <div id="O’Neill--2016"></div> O’Neill, B.C. et al., 2016: The Scenario Model Intercomparison Project (ScenarioMIP) for CMIP6. ''Geoscientific Model Development'' , '''9(9)''' , 3461–3482, doi: . <div id="O’Neill--2017"></div> O’Neill, B.C. et al., 2017: IPCC reasons for concern regarding climate change risks. ''Nature Climate Change'' , '''7(1)''' , 28–37, doi: . <div id="O’Reilly--2020"></div> O’Reilly, C.H., D.J. Befort, and A. Weisheimer, 2020: Calibrating large-ensemble European climate projections using observational data. ''Earth System Dynamics'' , '''11(4)''' , 1033–1049, doi: . <div id="Oelsmann--2020"></div> Oelsmann, J., L. Borchert, R. Hand, J. Baehr, and J.H. Jungclaus, 2020: Linking Ocean Forcing and Atmospheric Interactions to Atlantic Multidecadal Variability in MPI-ESM1.2. ''Geophysical Research Letters'' , '''47(10)''' , e2020GL087259, doi: . <div id="Ohba--2013"></div> Ohba, M., H. Shiogama, T. Yokohata, and M. Watanabe, 2013: Impact of Strong Tropical Volcanic Eruptions on ENSO Simulated in a Coupled GCM. ''Journal of Climate'' , '''26(14)''' , 5169–5182, doi: . <div id="Oldenburg--2018"></div> Oldenburg, D., K.C. Armour, L.A.A. Thompson, and C.M. Bitz, 2018: Distinct Mechanisms of Ocean Heat Transport Into the Arctic Under Internal Variability and Climate Change. ''Geophysical Research Letters'' , '''45(15)''' , 7692–7700, doi: . <div id="Olonscheck--2017"></div> Olonscheck, D. and D. Notz, 2017: Consistently Estimating Internal Climate Variability from Climate Model Simulations. ''Journal of Climate'' , '''30(23)''' , 9555–9573, doi: . <div id="Olson--2019"></div> Olson, R. et al., 2019: A novel method to test non-exclusive hypotheses applied to Arctic ice projections from dependent models. ''Nature Communications'' , '''10(1)''' , 3016, doi: . <div id="Onarheim--2015"></div> Onarheim, I.H., T. Eldevik, M. Årthun, R.B. Ingvaldsen, and L.H. Smedsrud, 2015: Skillful prediction of Barents Sea ice cover. ''Geophysical Research Letters'' , '''42(13)''' , 5364–5371, doi: . <div id="Osborn--2018"></div> Osborn, T.J., C.J. Wallace, J.A. Lowe, and D. Bernie, 2018: Performance of Pattern-Scaled Climate Projections under High-End Warming. Part I: Surface Air Temperature over Land. ''Journal of Climate'' , '''31(14)''' , 5667–5680, doi: . <div id="Oschlies--2010"></div> Oschlies, A., M. Pahlow, A. Yool, and R.J. Matear, 2010: Climate engineering by artificial ocean upwelling: Channelling the sorcerer’s apprentice. ''Geophysical Research Letters'' , '''37(4)''' , 1–5, doi: . <div id="Oudar--2020"></div> Oudar, T., J. Cattiaux, and H. Douville, 2020: Drivers of the Northern Extratropical Eddy-Driven Jet Change in CMIP5 and CMIP6 Models. ''Geophysical Research Letters'' , '''47(8)''' , e2019GL086695, doi: . <div id="Oudar--2017"></div> Oudar, T. et al., 2017: Respective roles of direct GHG radiative forcing and induced Arctic sea ice loss on the Northern Hemisphere atmospheric circulation. ''Climate Dynamics'' , '''49(11–12)''' , 3693–3713, doi: . <div id="Paik--2018"></div> Paik, S. and S.K. Min, 2018: Assessing the impact of volcanic eruptions on climate extremes using CMIP5 models. ''Journal of Climate'' , '''31(14)''' , 5333–5349, doi: . <div id="Paik--2020"></div> Paik, S., S.K. Min, C.E. Iles, E.M. Fischer, and A.P. Schurer, 2020: Volcanic-induced global monsoon drying modulated by diverse El Ninõ responses. ''Science Advances'' , '''6(21)''' , 1–9, doi: . <div id="Palter--2018"></div> Palter, J.B., T.L. Frölicher, D. Paynter, and J.G. John, 2018: Climate, ocean circulation, and sea level changes under stabilization and overshoot pathways to 1.5 K warming. ''Earth System Dynamics'' , '''9(2)''' , 817–828, doi: . <div id="Park--2019"></div> Park, J.-Y., C.A. Stock, J.P. Dunne, X. Yang, and A. Rosati, 2019: Seasonal to multiannual marine ecosystem prediction with a global Earth system model. ''Science'' , '''365(6450)''' , 284–288, doi: . <div id="Parker--2009"></div> Parker, W.S., 2009: II – Confirmation and adequacy-for-Purpose in Climate Modelling. ''Aristotelian Society Supplementary Volume'' , '''83(1)''' , 233–249, doi: . <div id="Parsons--2020"></div> Parsons, L.A., M.K. Brennan, R.C.J. Wills, and C. Proistosescu, 2020: Magnitudes and Spatial Patterns of Interdecadal Temperature Variability in CMIP6. ''Geophysical Research Letters'' , '''47(7)''' , e2019GL086588, doi: . <div id="Parsons--2016"></div> Parsons, S., J.A. Renwick, and A.J. McDonald, 2016: An Assessment of Future Southern Hemisphere Blocking Using CMIP5 Projections from Four GCMs. ''Journal of Climate'' , '''29(21)''' , 7599–7611, doi: . <div id="Partanen--2012"></div> Partanen, A.-I. et al., 2012: Direct and indirect effects of sea spray geoengineering and the role of injected particle size. ''Journal of Geophysical Research: Atmospheres'' , '''117(D2)''' , D02203, doi: . <div id="Pascale--2017"></div> Pascale, S. et al., 2017: Weakening of the North American monsoon with global warming. ''Nature Climate Change'' , '''7(11)''' , 806–812, doi: . <div id="Pasternack--2018"></div> Pasternack, A. et al., 2018: Parametric decadal climate forecast recalibration (DeFoReSt 1.0). ''Geoscientific Model Development'' , '''11(1)''' , 351–368, doi: . <div id="Pausata--2015"></div> Pausata, F.S.R., L. Chafik, R. Caballero, and D.S. Battisti, 2015: Impacts of high-latitude volcanic eruptions on ENSO and AMOC. ''Proceedings of the National Academy of Sciences'' , '''112(45)''' , 13784–13788, doi: . <div id="Paxian--2019"></div> Paxian, A. et al., 2019: User-oriented global predictions of the GPCC drought index for the next decade. ''Meteorologische Zeitschrift'' , '''28(1)''' , 3–21, doi: . <div id="Peings--2017"></div> Peings, Y., J. Cattiaux, S. Vavrus, and G. Magnusdottir, 2017: Late twenty-first-century changes in the midlatitude atmospheric circulation in the CESM large ensemble. ''Journal of Climate'' , '''30(15)''' , 5943–5960, doi: . <div id="Peings--2018"></div> Peings, Y., J. Cattiaux, S.J. Vavrus, and G. Magnusdottir, 2018: Projected squeezing of the wintertime North-Atlantic jet. ''Environmental Research Letters'' , '''13(7)''' , 74016, doi: . <div id="Pendergrass--2014"></div> Pendergrass, A.G. and D.L. Hartmann, 2014: The Atmospheric Energy Constraint on Global-Mean Precipitation Change. ''Journal of Climate'' , '''27(2)''' , 757–768, doi: . <div id="Pendergrass--2017"></div> Pendergrass, A.G., R. Knutti, F. Lehner, C. Deser, and B.M. Sanderson, 2017: Precipitation variability increases in a warmer climate. ''Scientific Reports'' , '''7(1)''' , 17966, doi: . <div id="Penner--2015"></div> Penner, J.E., C. Zhou, and X. Liu, 2015: Can cirrus cloud seeding be used for geoengineering? ''Geophysical Research Letters'' , '''42(20)''' , 8775–8782, doi: . <div id="Peters--2011"></div> Peters, G.P., B. Aamaas, T. Berntsen, and J.S. Fuglestvedt, 2011: The integrated global temperature change potential (iGTP) and relationships between emission metrics. ''Environmental Research Letters'' , '''6(4)''' , 044021, doi: . <div id="Peters--2017"></div> Peters, G.P. et al., 2017: Towards real-time verification of CO <sub>2</sub> emissions. ''Nature Climate Change'' , '''7(12)''' , 848–850, doi: . <div id="Pfahl--2015"></div> Pfahl, S., P.A. O’Gorman, and M.S. Singh, 2015: Extratropical Cyclones in Idealized Simulations of Changed Climates. ''Journal of Climate'' , '''28(23)''' , 9373–9392, doi: . <div id="Piani--2005"></div> Piani, C., D.J. Frame, D.A. Stainforth, and M.R. Allen, 2005: Constraints on climate change from a multi-thousand member ensemble of simulations. ''Geophysical Research Letters'' , '''32(23)''' , L23825, doi: . <div id="Pitari--2014"></div> Pitari, G. et al., 2014: Stratospheric ozone response to sulfate geoengineering: Results from the Geoengineering Model Intercomparison Project (GeoMIP). ''Journal of Geophysical Research: Atmospheres'' , '''119(5)''' , 2629–2653, doi: . <div id="Pithan--2014"></div> Pithan, F. and T. Mauritsen, 2014: Arctic amplification dominated by temperature feedbacks in contemporary climate models. ''Nature Geoscience'' , '''7(3)''' , 181–184, doi: . <div id="Plazzotta--2019"></div> Plazzotta, M., R. Séférian, and H. Douville, 2019: Impact of Solar Radiation Modification on Allowable CO <sub>2</sub> Emissions: What Can We Learn From Multimodel Simulations? ''Earth’s Future'' , '''7(6)''' , 664–676, doi: . <div id="Plazzotta--2018"></div> Plazzotta, M., R. Séférian, H. Douville, B. Kravitz, and J. Tjiputra, 2018: Land Surface Cooling Induced by Sulfate Geoengineering Constrained by Major Volcanic Eruptions. ''Geophysical Research Letters'' , '''45''' , 5663–5671, doi: . <div id="Pohlmann--2017"></div> Pohlmann, H., J. Kröger, R.J. Greatbatch, and W.A. Müller, 2017: Initialization shock in decadal hindcasts due to errors in wind stress over the tropical Pacific. ''Climate Dynamics'' , '''49(7–8)''' , 2685–2693, doi: . <div id="Pohlmann--2009"></div> Pohlmann, H., J.H. Jungclaus, A. Köhl, D. Stammer, and J. Marotzke, 2009: Initializing Decadal Climate Predictions with the GECCO Oceanic Synthesis: Effects on the North Atlantic. ''Journal of Climate'' , '''22(14)''' , 3926–3938, doi: . <div id="Pohlmann--2013"></div> Pohlmann, H. et al., 2013: Improved forecast skill in the tropics in the new MiKlip decadal climate predictions. ''Geophysical Research Letters'' , '''40(21)''' , 5798–5802, doi: . <div id="Pohlmann--2019"></div> Pohlmann, H. et al., 2019: Realistic Quasi-Biennial Oscillation Variability in Historical and Decadal Hindcast Simulations Using CMIP6 Forcing. ''Geophysical Research Letters'' , '''46(23)''' , 14118–14125, doi: . <div id="Polkova--2014"></div> Polkova, I., A. Köhl, and D. Stammer, 2014: Impact of initialization procedures on the predictive skill of a coupled ocean–atmosphere model. ''Climate Dynamics'' , '''42(11–12)''' , 3151–3169, doi: . <div id="Polkova--2019"></div> Polkova, I. et al., 2019: Initialization and Ensemble Generation for Decadal Climate Predictions: A Comparison of Different Methods. ''Journal of Advances in Modeling Earth Systems'' , '''11(1)''' , 149–172, doi: . <div id="Polson--2017"></div> Polson, D. and G.C. Hegerl, 2017: Strengthening contrast between precipitation in tropical wet and dry regions. ''Geophysical Research Letters'' , '''44(1)''' , 365–373, doi: . <div id="Polson--2014"></div> Polson, D., M. Bollasina, G.C. Hegerl, and L.J. Wilcox, 2014: Decreased monsoon precipitation in the Northern Hemisphere due to anthropogenic aerosols. ''Geophysical Research Letters'' , '''41(16)''' , 6023–6029, doi: . <div id="Polvani--2020"></div> Polvani, L.M., M. Previdi, M.R. England, G. Chiodo, and K.L. Smith, 2020: Substantial twentieth-century Arctic warming caused by ozone-depleting substances. ''Nature Climate Change'' , '''10(2)''' , 130–133, doi: . <div id="Pope--2012"></div> Pope, F.D. et al., 2012: Stratospheric aerosol particles and solar-radiation management. ''Nature Climate Change'' , '''2(10)''' , 713–719, doi: . <div id="Power--2012"></div> Power, S.B., F. Delage, R. Colman, and A. Moise, 2012: Consensus on Twenty-First-Century Rainfall Projections in Climate Models More Widespread than Previously Thought. ''Journal of Climate'' , '''25(11)''' , 3792–3809, doi: . <div id="Power--2013"></div> Power, S.B., F. Delage, C. Chung, G. Kociuba, and K. Keay, 2013: Robust twenty-first-century projections of El Niño and related precipitation variability. ''Nature'' , '''502(7472)''' , 541–545, doi: . <div id="Predybaylo--2017"></div> Predybaylo, E., G.L. Stenchikov, A.T. Wittenberg, and F. Zeng, 2017: Impacts of a Pinatubo-size volcanic eruption on ENSO. ''Journal of Geophysical Research: Atmospheres'' , '''122(2)''' , 925–947, doi: . <div id="Predybaylo--2020"></div> Predybaylo, E., G. Stenchikov, A.T. Wittenberg, and S. Osipov, 2020: El Niño/Southern Oscillation response to low-latitude volcanic eruptions depends on ocean pre-conditions and eruption timing. ''Communications Earth & Environment'' , '''1(1)''' , 1–13, doi: . <div id="Priestley--2020"></div> Priestley, M.D.K. et al., 2020: An Overview of the Extratropical Storm Tracks in CMIP6 Historical Simulations. ''Journal of Climate'' , '''33(15)''' , 6315–6343, doi: . <div id="Pugh--2018"></div> Pugh, T.A.M. et al., 2018: A Large Committed Long-Term Sink of Carbon due to Vegetation Dynamics. ''Earth’s Future'' , '''6(10)''' , 1413–1432, doi: . <div id="Raible--2016"></div> Raible, C.C. et al., 2016: Tambora 1815 as a test case for high impact volcanic eruptions: Earth system effects. ''WIREs Climate Change'' , '''7(4)''' , 569–589, doi: . <div id="Ramanathan--2008"></div> Ramanathan, V. and Y. Feng, 2008: On avoiding dangerous anthropogenic interference with the climate system: Formidable challenges ahead. ''Proceedings of the National Academy of Sciences'' , '''105(38)''' , 14245–14250, doi: . <div id="Ramanathan--2005"></div> Ramanathan, V. et al., 2005: Atmospheric brown clouds: Impacts on South Asian climate and hydrological cycle. ''Proceedings of the National Academy of Sciences'' , '''102(15)''' , 5326–5333, doi: . <div id="Randerson--2015"></div> Randerson, J.T. et al., 2015: Multicentury changes in ocean and land contributions to the climate–carbon feedback. ''Global Biogeochemical Cycles'' , '''29(6)''' , 744–759, doi: . <div id="Rao--2017"></div> Rao, S. et al., 2017: Future air pollution in the Shared Socio-economic Pathways. ''Global Environmental Change'' , '''42''' , 346–358, doi: . <div id="Regayre--2018"></div> Regayre, L.A. et al., 2018: Aerosol and physical atmosphere model parameters are both important sources of uncertainty in aerosol ERF. ''Atmospheric Chemistry and Physics'' , '''18(13)''' , 9975–10006, doi: . <div id="Riahi--2017"></div> Riahi, K. et al., 2017: The Shared Socioeconomic Pathways and their energy, land use, and greenhouse gas emissions implications: An overview. ''Global Environmental Change'' , '''42''' , 153–168, doi: . <div id="Ribes--2021"></div> Ribes, A., S. Qasmi, and N.P. Gillett, 2021: Making climate projections conditional on historical observations. ''Science Advances'' , '''7(4)''' , eabc0671, doi: . <div id="Richardson--2016"></div> Richardson, T.B., P.M. Forster, T. Andrews, and D.J. Parker, 2016: Understanding the Rapid Precipitation Response to CO <sub>2</sub> and Aerosol Forcing on a Regional Scale. ''Journal of Climate'' , '''29(2)''' , 583–594, doi: . <div id="Richardson--2018a"></div> Richardson, T.B. et al., 2018a: Drivers of Precipitation Change: An Energetic Understanding. ''Journal of Climate'' , '''31(23)''' , 9641–9657, doi: . <div id="Richardson--2018b"></div> Richardson, T.B. et al., 2018b: Carbon Dioxide Physiological Forcing Dominates Projected Eastern Amazonian Drying. ''Geophysical Research Letters'' , '''45(6)''' , 2815–2825, doi: . <div id="Richardson--2019"></div> Richardson, T.B. et al., 2019: Efficacy of Climate Forcings in PDRMIP Models. ''Journal of Geophysical Research: Atmospheres'' , '''124(23)''' , 12824–12844, doi: . <div id="Richter Jadwiga--2018"></div> Richter Jadwiga, H. et al., 2018: Stratospheric Response in the First Geoengineering Simulation Meeting Multiple Surface Climate Objectives. ''Journal of Geophysical Research: Atmospheres'' , '''123(11)''' , 5762–5782, doi: . <div id="Ricke--2014"></div> Ricke, K.L. and K. Caldeira, 2014: Maximum warming occurs about one decade after a carbon dioxide emission. ''Environmental Research Letters'' , '''9(12)''' , 124002, doi: . <div id="Rickels--2018"></div> Rickels, W., F. Reith, D. Keller, A. Oschlies, and M.F. Quaas, 2018: Integrated Assessment of Carbon Dioxide Removal. ''Earth’s Future'' , '''6(3)''' , 565–582, doi: . <div id="Ridley--2015"></div> Ridley, H.E. et al., 2015: Aerosol forcing of the position of the intertropical convergence zone since ad 1550. ''Nature Geoscience'' , '''8(3)''' , 195–200, doi: . <div id="Rind--2018"></div> Rind, D. et al., 2018: Multicentury Instability of the Atlantic Meridional Circulation in Rapid Warming Simulations With GISS ModelE2. ''Journal of Geophysical Research: Atmospheres'' , '''123(12)''' , 6331–6355, doi: . <div id="Robock--1983"></div> Robock, A., 1983: Ice and Snow Feedbacks and the Latitudinal and Seasonal Distribution of Climate Sensitivity. ''Journal of the Atmospheric Sciences'' , '''40(4)''' , 986–997, doi: . <div id="Robock--2010"></div> Robock, A., M. Bunzl, B. Kravitz, and G.L. Stenchikov, 2010: A Test for Geoengineering? ''Science'' , '''327(5965)''' , 530–531, doi: . <div id="Robock--2013"></div> Robock, A., D.G. MacMartin, R. Duren, and M.W. Christensen, 2013: Studying geoengineering with natural and anthropogenic analogs. ''Climatic Change'' , '''121(3)''' , 445–458, doi: . <div id="Robson--2012"></div> Robson, J.I., R.T. Sutton, and D.M. Smith, 2012: Initialized decadal predictions of the rapid warming of the North Atlantic Ocean in the mid 1990s. ''Geophysical Research Letters'' , '''39(19)''' , L19713, doi: . <div id="Robson--2014"></div> Robson, J.I., R.T. Sutton, and D.M. Smith, 2014: Decadal predictions of the cooling and freshening of the North Atlantic in the 1960s and the role of ocean circulation. ''Climate Dynamics'' , '''42(9)''' , 2353–2365, doi: . <div id="Rodgers--2015"></div> Rodgers, K.B., J. Lin, and T.L. Frölicher, 2015: Emergence of multiple ocean ecosystem drivers in a large ensemble suite with an Earth system model. ''Biogeosciences'' , '''12(11)''' , 3301–3320, doi: . <div id="Rogelj--2014"></div> Rogelj, J. et al., 2014: Disentangling the effects of CO <sub>2</sub> and short-lived climate forcer mitigation. ''Proceedings of the National Academy of Sciences'' , '''111(46)''' , 16325–16330, doi: . <div id="Rogelj--2018a"></div> Rogelj, J. et al., 2018a: Scenarios towards limiting global mean temperature increase below 1.5°C. ''Nature Climate Change'' , '''8(4)''' , 325–332, doi: . <div id="Rogelj--2018b"></div> Rogelj, J. et al., 2018b: Mitigation Pathways Compatible with 1.5°C in the Context of Sustainable Development Supplementary Material. In: ''Global Warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways, in the context of strengthening the global response to the threat of climate change,'' ''sustainable development, and efforts to eradicate poverty'' [Masson-Delmotte, V., P. Zhai, H.-O. Pörtner, D. Roberts, J. Skea, P.R. Shukla, A. Pirani, W. Moufouma-Okia, C. Péan, R. Pidcock, S. Connors, J.B.R. Matthews, Y. Chen, X. Zhou, M.I. Gomis, E. Lonnoy, T. Maycock, M. Tignor, and T. Waterfield (eds.)]. In Press, pp. 2SM: 1–50, . <div id="Rotstayn--2013"></div> Rotstayn, L.D., 2013: Projected effects of declining anthropogenic aerosols on the southern annular mode. ''Environmental Research Letters'' , '''8(4)''' , 044028, doi: . <div id="Rowell--2012"></div> Rowell, D.P., 2012: Sources of uncertainty in future changes in local precipitation. ''Climate Dynamics'' , '''39(7–8)''' , 1929–1950, doi: . <div id="Ruggieri--2021"></div> Ruggieri, P. et al., 2021: Atlantic Multidecadal Variability and North Atlantic Jet: A Multimodel View from the Decadal Climate Prediction Project. ''Journal of Climate'' , '''34(1)''' , 347–360, doi: . <div id="Ruprich-Robert--2015"></div> Ruprich-Robert, Y. and C. Cassou, 2015: Combined influences of seasonal East Atlantic Pattern and North Atlantic Oscillation to excite Atlantic multidecadal variability in a climate model. ''Climate Dynamics'' , '''44(1–2)''' , 229–253, doi: . <div id="Russotto--2018"></div> Russotto, R.D. and T.P. Ackerman, 2018: Changes in clouds and thermodynamics under solar geoengineering and implications for required solar reduction. ''Atmospheric Chemistry and Physics'' , '''18(16)''' , 11905–11925, doi: . <div id="Saffioti--2017"></div> Saffioti, C., E.M. Fischer, and R. Knutti, 2017: Improved Consistency of Climate Projections over Europe after Accounting for Atmospheric Circulation Variability. ''Journal of Climate'' , '''30(18)''' , 7271–7291, doi: . <div id="Saggioro--2019"></div> Saggioro, E. and T.G. [[#Shepherd--2019|Shepherd, 2019]] : Quantifying the Timescale and Strength of Southern Hemisphere Intraseasonal Stratosphere-troposphere Coupling. ''Geophysical Research Letters'' , '''46(22)''' , 13479–13487, doi: . <div id="Samset--2020"></div> Samset, B.H., J.S. Fuglestvedt, and M.T. Lund, 2020: Delayed emergence of a global temperature response after emission mitigation. ''Nature Communications'' , '''11(1)''' , 3261, doi: . <div id="Samset--2016"></div> Samset, B.H. et al., 2016: Fast and slow precipitation responses to individual climate forcers: A PDRMIP multimodel study. ''Geophysical Research Letters'' , '''43(6)''' , 2782–2791, doi: . <div id="Sanchez-Gomez--2016"></div> Sanchez-Gomez, E., C. Cassou, Y. Ruprich-Robert, E. Fernandez, and L. Terray, 2016: Drift dynamics in a coupled model initialized for decadal forecasts. ''Climate Dynamics'' , '''46(5–6)''' , 1819–1840, doi: . <div id="Sand--2016"></div> Sand, M. et al., 2016: Response of Arctic temperature to changes in emissions of short-lived climate forcers. ''Nature Climate Change'' , '''6(3)''' , 286–289, doi: . <div id="Sanderson--2015"></div> Sanderson, B.M., R. Knutti, and P. Caldwell, 2015: Addressing Interdependency in a Multimodel Ensemble by Interpolation of Model Properties. ''Journal of Climate'' , '''28(13)''' , 5150–5170, doi: . <div id="Sanderson--2017"></div> Sanderson, B.M., M. Wehner, and R. Knutti, 2017: Skill and independence weighting for multi-model assessments. ''Geoscientific Model Development'' , '''10(6)''' , 2379–2395, doi: . <div id="Sanderson--2011"></div> Sanderson, B.M. et al., 2011: The response of the climate system to very high greenhouse gas emission scenarios. ''Environmental Research Letters'' , '''6(3)''' , 034005, doi: . <div id="Santer--2014"></div> Santer, B.D. et al., 2014: Volcanic contribution to decadal changes in tropospheric temperature. ''Nature Geoscience'' , '''7(3)''' , 185–189, doi: . <div id="Santer--2018"></div> Santer, B.D. et al., 2018: Human influence on the seasonal cycle of tropospheric temperature. ''Science'' , '''361(6399)''' , eaas8806, doi: . <div id="Scaife--2018"></div> Scaife, A.A. and D. Smith, 2018: A signal-to-noise paradox in climate science. ''npj Climate and Atmospheric Science'' , '''1(1)''' , 28, doi: . <div id="Scaife--2014"></div> Scaife, A.A. et al., 2014: Predictability of the quasi-biennial oscillation and its northern winter teleconnection on seasonal to decadal timescales. ''Geophysical Research Letters'' , '''41(5)''' , 1752–1758, doi: . <div id="Schäfer--2015"></div> Schäfer, S. et al. (eds.), 2015: ''The European Transdisciplinary Assessment of Climate Engineering (EuTRACE): Removing Greenhouse Gases from the Atmosphere and Reflecting Sunlight away from Earth'' . Funded by the European Union’s Seventh Framework Programme under Grant Agreement 306993, Institute for Advanced Sustainability Studies (IASS), Potsdam, Germany, 170 pp., doi: . <div id="Schleussner--2017"></div> Schleussner, C.-F., P. Pfleiderer, and E.M. Fischer, 2017: In the observational record half a degree matters. ''Nature Climate Change'' , '''7(7)''' , 460–462, doi: . <div id="Schleussner--2016"></div> Schleussner, C.-F. et al., 2016: Differential climate impacts for policy-relevant limits to global warming: the case of 1.5°C and 2°C. ''Earth System Dynamics'' , '''7(2)''' , 327–351, doi: . <div id="Schloesser--2019"></div> Schloesser, F., T. Friedrich, A. Timmermann, R.M. DeConto, and D. Pollard, 2019: Antarctic iceberg impacts on future Southern Hemisphere climate. ''Nature Climate Change'' , '''9(9)''' , 672–677, doi: . <div id="Schmidt--2014"></div> Schmidt, G.A. et al., 2014: Using palaeo-climate comparisons to constrain future projections in CMIP5. ''Climate of the Past'' , '''10(1)''' , 221–250, doi: . <div id="Schmidt--2012"></div> Schmidt, H. et al., 2012: Solar irradiance reduction to counteract radiative forcing from a quadrupling of CO <sub>2</sub> : Climate responses simulated by four earth system models. ''Earth System Dynamics'' , '''3(1)''' , 63–78, doi: . <div id="Schneider--2001"></div> Schneider, S.H., 2001: What is ’dangerous’ climate change? ''Nature'' , '''411(6833)''' , 17–19, doi: . <div id="Schneider--2002"></div> Schneider, S.H., 2002: Can we estimate the likelihood of climatic changes at 2100? ''Climatic Change'' , '''52(4)''' , 441–451, doi: . <div id="Schneider--2015"></div> Schneider, T., T. Bischoff, and H. Płotka, 2015: Physics of Changes in Synoptic Midlatitude Temperature Variability. ''Journal of Climate'' , '''28(6)''' , 2312–2331, doi: . <div id="Schurer--2014"></div> Schurer, A.P., S.F.B. Tett, and G.C. Hegerl, 2014: Small influence of solar variability on climate over the past millennium. ''Nature Geoscience'' , '''7(2)''' , 104–108, doi: . <div id="Schurer--2013"></div> Schurer, A.P., G.C. Hegerl, M.E. Mann, S.F.B. Tett, and S.J. Phipps, 2013: Separating Forced from Chaotic Climate Variability over the Past Millennium. ''Journal of Climate'' , '''26(18)''' , 6954–6973, doi: . <div id="Schurer--2018"></div> Schurer, A.P. et al., 2018: Interpretations of the Paris climate target. ''Nature Geoscience'' , '''11(4)''' , 220–221, doi: . <div id="Schuster--2019"></div> Schuster, M. et al., 2019: Improvement in the decadal prediction skill of the North Atlantic extratropical winter circulation through increased model resolution. ''Earth System Dynamics'' , '''10(4)''' , 901–917, doi: . <div id="Schwartzman--2020"></div> Schwartzman, A. and R.F. Keeling, 2020: Achieving atmospheric verification of CO <sub>2</sub> emissions. ''Nature Climate Change'' , '''10(5)''' , 416–417, doi: . <div id="Schwierz--2004"></div> Schwierz, C., M. Croci-Maspoli, and H.C. Davies, 2004: Perspicacious indicators of atmospheric blocking. ''Geophysical Research Letters'' , '''31(6)''' , L06125, doi: . <div id="Schwinger--2018"></div> Schwinger, J. and J. Tjiputra, 2018: Ocean Carbon Cycle Feedbacks Under Negative Emissions. ''Geophysical Research Letters'' , '''45(10)''' , 5062–5070, doi: . <div id="Screen--2014"></div> Screen, J.A., 2014: Arctic amplification decreases temperature variance in northern mid- to high-latitudes. ''Nature Climate Change'' , '''4(7)''' , 577–582, doi: . <div id="Screen--2018"></div> Screen, J.A., 2018: Arctic sea ice at 1.5 and 2°C. ''Nature Climate Change'' , '''8(5)''' , 362–363, doi: . <div id="Screen--2017"></div> Screen, J.A. and D. Williamson, 2017: Ice-free Arctic at 1.5°C? ''Nature Climate Change'' , '''7(4)''' , 230–231, doi: . <div id="Screen--2018a"></div> Screen, J.A., T.J. Bracegirdle, and I. Simmonds, 2018a: Polar Climate Change as Manifest in Atmospheric Circulation. ''Current Climate Change Reports'' , '''4(4)''' , 383–395, doi: . <div id="Screen--2018b"></div> Screen, J.A. et al., 2018b: Consistency and discrepancy in the atmospheric response to Arctic sea-ice loss across climate models. ''Nature Geoscience'' , '''11(3)''' , 155–163, doi: . <div id="Seager--2014a"></div> Seager, R. et al., 2014a: Causes of Increasing Aridification of the Mediterranean Region in Response to Rising Greenhouse Gases. ''Journal of Climate'' , '''27(12)''' , 4655–4676, doi: . <div id="Seager--2014b"></div> Seager, R. et al., 2014b: Dynamical and Thermodynamical Causes of Large-Scale Changes in the Hydrological Cycle over North America in Response to Global Warming. ''Journal of Climate'' , '''27(20)''' , 7921–7948, doi: . <div id="Seiler--2016"></div> Seiler, C. and F.W. Zwiers, 2016: How will climate change affect explosive cyclones in the extratropics of the Northern Hemisphere? ''Climate Dynamics'' , '''46(11–12)''' , 3633–3644, doi: . <div id="Sellar--2019"></div> Sellar, A.A. et al., 2019: UKESM1: Description and Evaluation of the U.K. Earth System Model. ''Journal of Advances in Modeling Earth Systems'' , '''11(12)''' , 4513–4558, doi: . <div id="Seneviratne--2006"></div> Seneviratne, S.I., D. Lüthi, M. Litschi, and C. Schär, 2006: Land–atmosphere coupling and climate change in Europe. ''Nature'' , '''443(7108)''' , 205–209, doi: . <div id="Seneviratne--2016"></div> Seneviratne, S.I., M.G. Donat, A.J. Pitman, R. Knutti, and R.L. Wilby, 2016: Allowable CO <sub>2</sub> emissions based on regional and impact-related climate targets. ''Nature'' , '''529(7587)''' , 477–483, doi: . <div id="Seneviratne--2018"></div> Seneviratne, S.I. et al., 2018: Climate extremes, land–climate feedbacks and land-use forcing at 1.5°C. ''Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences'' , '''376(2119)''' , 20160450, doi: . <div id="Serreze--2011"></div> Serreze, M.C. and R.G. Barry, 2011: Processes and impacts of Arctic amplification: A research synthesis. ''Global and Planetary Change'' , '''77(1–2)''' , 85–96, doi: . <div id="Servain--2014"></div> Servain, J., G. Caniaux, Y.K. Kouadio, M.J. McPhaden, and M. Araujo, 2014: Recent climatic trends in the tropical Atlantic. ''Climate Dynamics'' , '''43(11)''' , 3071–3089, doi: . <div id="Seviour--2019"></div> Seviour, W.J.M. et al., 2019: The Southern Ocean Sea Surface Temperature Response to Ozone Depletion: A Multimodel Comparison. ''Journal of Climate'' , '''32(16)''' , 5107–5121, doi: . <div id="Sexton--2012"></div> Sexton, D.M.H., J.M. Murphy, M. Collins, and M.J. Webb, 2012: Multivariate probabilistic projections using imperfect climate models part I: outline of methodology. ''Climate Dynamics'' , '''38(11–12)''' , 2513–2542, doi: . <div id="Sgubin--2015"></div> Sgubin, G., D. Swingedouw, S. Drijfhout, S. Hagemann, and E. Robertson, 2015: Multimodel analysis on the response of the AMOC under an increase of radiative forcing and its symmetrical reversal. ''Climate Dynamics'' , '''45(5–6)''' , 1429–1450, doi: . <div id="Shaffrey--2017"></div> Shaffrey, L.C. et al., 2017: Decadal predictions with the HiGEM high resolution global coupled climate model: description and basic evaluation. ''Climate Dynamics'' , '''48(1–2)''' , 297–311, doi: . <div id="Shaw--2019"></div> Shaw, T.A., 2019: Mechanisms of Future Predicted Changes in the Zonal Mean Mid-Latitude Circulation. ''Current Climate Change Reports'' , '''5(4)''' , 345–357, doi: . <div id="Shaw--2015"></div> Shaw, T.A. and A. Voigt, 2015: Tug of war on summertime circulation between radiative forcing and sea surface warming. ''Nature Geoscience'' , '''8(7)''' , 560–566, doi: . <div id="Shaw--2016"></div> Shaw, T.A. et al., 2016: Storm track processes and the opposing influences of climate change. ''Nature Geoscience'' , '''9(9)''' , 656–664, doi: . <div id="Shawki--2018"></div> Shawki, D., A. Voulgarakis, A. Chakraborty, M. Kasoar, and J. Srinivasan, 2018: The South Asian Monsoon Response to Remote Aerosols: Global and Regional Mechanisms. ''Journal of Geophysical Research: Atmospheres'' , '''123(20)''' , 11585–11601, doi: . <div id="Sheen--2017"></div> Sheen, K.L. et al., 2017: Skilful prediction of Sahel summer rainfall on inter-annual and multi-year timescales. ''Nature Communications'' , '''8(1)''' , 14966, doi: . <div id="Shepherd--2014"></div> Shepherd, T.G., 2014: Atmospheric circulation as a source of uncertainty in climate change projections. ''Nature Geoscience'' , '''7(10)''' , 703–708, doi: . <div id="Shepherd--2019"></div> Shepherd, T.G., 2019: Storyline approach to the construction of regional climate change information. ''Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences'' , '''475(2225)''' , 20190013, doi: . <div id="Shepherd--2018"></div> Shepherd, T.G. et al., 2018: Storylines: an alternative approach to representing uncertainty in physical aspects of climate change. ''Climatic Change'' , '''151(3–4)''' , 555–571, doi: . <div id="Sherwood--2015"></div> Sherwood, S.C. et al., 2015: Adjustments in the Forcing–Feedback Framework for Understanding Climate Change. ''Bulletin of the American Meteorological Society'' , '''96(2)''' , 217–228, doi: . <div id="Shindell--2019"></div> Shindell, D. and C.J. Smith, 2019: Climate and air-quality benefits of a realistic phase-out of fossil fuels. ''Nature'' , '''573(7774)''' , 408–411, doi: . <div id="Shindell--2017"></div> Shindell, D. et al., 2017: A climate policy pathway for near- and long-term benefits. ''Science'' , '''356(6337)''' , 493–494, doi: . <div id="Shiogama--2016"></div> Shiogama, H. et al., 2016: Predicting future uncertainty constraints on global warming projections. ''Scientific Reports'' , '''6(1)''' , 18903, doi: . <div id="Shu--2015"></div> Shu, Q., Z. Song, and F. Qiao, 2015: Assessment of sea ice simulations in the CMIP5 models. ''The Cryosphere'' , '''9(1)''' , 399–409, doi: . <div id="Sienz--2016"></div> Sienz, F., W.A. Müller, and H. Pohlmann, 2016: Ensemble size impact on the decadal predictive skill assessment. ''Meteorologische Zeitschrift'' , '''25(6)''' , 645–655, doi: . <div id="Sigl--2015"></div> Sigl, M. et al., 2015: Timing and climate forcing of volcanic eruptions for the past 2,500 years. ''Nature'' , '''523(7562)''' , 543–549, doi: . <div id="Sigmond--2016"></div> Sigmond, M. and J.C. Fyfe, 2016: Tropical Pacific impacts on cooling North American winters. ''Nature Climate Change'' , '''6(10)''' , 970–974, doi: . <div id="Sigmond--2018"></div> Sigmond, M., J.C. Fyfe, and N.C. Swart, 2018: Ice-free Arctic projections under the Paris Agreement. ''Nature Climate Change'' , '''8(5)''' , 404–408, doi: . <div id="Sigmond--2020"></div> Sigmond, M., J.C. Fyfe, O.A. Saenko, and N.C. Swart, 2020: Ongoing AMOC and related sea-level and temperature changes after achieving the Paris targets. ''Nature Climate Change'' , '''10(7)''' , 672–677, doi: . <div id="Siler--2019"></div> Siler, N., G.H. Roe, K.C. Armour, and N. Feldl, 2019: Revisiting the surface-energy-flux perspective on the sensitivity of global precipitation to climate change. ''Climate Dynamics'' , '''52(7)''' , 3983–3995, doi: . <div id="Sime--2019"></div> Sime, L.C., P.O. Hopcroft, and R.H. Rhodes, 2019: Impact of abrupt sea ice loss on Greenland water isotopes during the last glacial period. ''Proceedings of the National Academy of Sciences'' , '''116(10)''' , 4099–4104, doi: . <div id="Simpson--2016"></div> Simpson, I.R. and L.M. Polvani, 2016: Revisiting the relationship between jet position, forced response, and annular mode variability in the southern midlatitudes. ''Geophysical Research Letters'' , '''43(6)''' , 2896–2903, doi: . <div id="Simpson--2014"></div> Simpson, I.R., T.A. Shaw, and R. Seager, 2014: A Diagnosis of the Seasonally and Longitudinally Varying Midlatitude Circulation Response to Global Warming. ''Journal of the Atmospheric Sciences'' , '''71(7)''' , 2489–2515, doi: . <div id="Simpson--2018"></div> Simpson, I.R., C. Deser, K.A. McKinnon, and E.A. Barnes, 2018: Modeled and Observed Multidecadal Variability in the North Atlantic Jet Stream and Its Connection to Sea Surface Temperatures. ''Journal of Climate'' , '''31(20)''' , 8313–8338, doi: . <div id="Simpson--2019a"></div> Simpson, I.R., S.G. Yeager, K.A. McKinnon, and C. Deser, 2019a: Decadal predictability of late winter precipitation in western Europe through an ocean–jet stream connection. ''Nature Geoscience'' , '''12(8)''' , 613–619, doi: . <div id="Simpson--2019b"></div> Simpson, I.R. et al., 2019b: The Regional Hydroclimate Response to Stratospheric Sulfate Geoengineering and the Role of Stratospheric Heating. ''Journal of Geophysical Research: Atmospheres'' , '''124(23)''' , 12587–12616, doi: . <div id="Singh--2017"></div> Singh, H.A., P.J. Rasch, and B.E.J. Rose, 2017: Increased Ocean Heat Convergence Into the High Latitudes With CO <sub>2</sub> Doubling Enhances Polar-Amplified Warming. ''Geophysical Research Letters'' , '''44(20)''' , 10583–10591, doi: . <div id="Sippel--2019"></div> Sippel, S. et al., 2019: Uncovering the Forced Climate Response from a Single Ensemble Member Using Statistical Learning. ''Journal of Climate'' , '''32(17)''' , 5677–5699, doi: . <div id="Smerdon--2017"></div> Smerdon, B.D., 2017: A synopsis of climate change effects on groundwater recharge. ''Journal of Hydrology'' , '''555''' , 125–128, doi: . <div id="Smith--2019"></div> Smith, C.J. et al., 2019: Current fossil fuel infrastructure does not yet commit us to 1.5°C warming. ''Nature Communications'' , '''10(1)''' , 101, doi: . <div id="Smith--2013a"></div> Smith, D.M., R. Eade, and H. Pohlmann, 2013a: A comparison of full-field and anomaly initialization for seasonal to decadal climate prediction. ''Climate Dynamics'' , '''41(11–12)''' , 3325–3338, doi: . <div id="Smith--2010"></div> Smith, D.M. et al., 2010: Skilful multi-year predictions of Atlantic hurricane frequency. ''Nature Geoscience'' , '''3(12)''' , 846–849, doi: . <div id="Smith--2013b"></div> Smith, D.M. et al., 2013b: Real-time multi-model decadal climate predictions. ''Climate Dynamics'' , '''41(11–12)''' , 2875–2888, doi: . <div id="Smith--2018"></div> Smith, D.M. et al., 2018: Predicted Chance That Global Warming Will Temporarily Exceed 1.5°C. ''Geophysical Research Letters'' , '''45(21)''' , 11895–11903, doi: . <div id="Smith--2019"></div> Smith, D.M. et al., 2019: Robust skill of decadal climate predictions. ''npj Climate and Atmospheric Science'' , '''2(1)''' , 13, doi: . <div id="Smith--2020"></div> Smith, D.M. et al., 2020: North Atlantic climate far more predictable than models imply. ''Nature'' , '''583(7818)''' , 796–800, doi: . <div id="Smith--2013"></div> Smith, S.J. and A. Mizrahi, 2013: Near-term climate mitigation by short-lived forcers. ''Proceedings of the National Academy of Sciences'' , '''110(35)''' , 14202–14206, doi: . <div id="Solaraju-Murali--2019"></div> Solaraju-Murali, B., L.-P. Caron, N. Gonzalez-Reviriego, and F.J. Doblas-Reyes, 2019: Multi-year prediction of European summer drought conditions for the agricultural sector. ''Environmental Research Letters'' , '''14(12)''' , 124014, doi: . <div id="Solomon--2016"></div> Solomon, A. and L.M. Polvani, 2016: Highly Significant Responses to Anthropogenic Forcings of the Midlatitude Jet in the Southern Hemisphere. ''Journal of Climate'' , '''29(9)''' , 3463–3470, doi: . <div id="Solomon--2009"></div> Solomon, S., G.-K. Plattner, R. Knutti, and P. Friedlingstein, 2009: Irreversible climate change due to carbon dioxide emissions. ''Proceedings of the National Academy of Sciences'' , '''106(6)''' , 1704–1709, doi: . <div id="Solomon--2016"></div> Solomon, S. et al., 2016: Emergence of healing in the Antarctic ozone layer. ''Science'' , '''353(6296)''' , 269–274, doi: . <div id="Solomon--2017"></div> Solomon, S. et al., 2017: Mirrored changes in Antarctic ozone and stratospheric temperature in the late 20th versus early 21st centuries. ''Journal of Geophysical Research: Atmospheres'' , '''122(16)''' , 8940–8950, doi: . <div id="Sonntag--2018"></div> Sonntag, S. et al., 2018: Quantifying and Comparing Effects of Climate Engineering Methods on the Earth System. ''Earth’s Future'' , '''6(2)''' , 149–168, doi: . <div id="Sospedra-Alfonso--2020"></div> Sospedra-Alfonso, R. and G.J. Boer, 2020: Assessing the Impact of Initialization on Decadal Prediction Skill. ''Geophysical Research Letters'' , '''47(4)''' , e2019GL086361, doi: . <div id="Spring--2020"></div> Spring, A., T. Ilyina, and J. Marotzke, 2020: Inherent uncertainty disguises attribution of reduced atmospheric CO <sub>2</sub> growth to CO <sub>2</sub> emission reductions for up to a decade. ''Environmental Research Letters'' , '''15(11)''' , 114058, doi: . <div id="Steffen--2018"></div> Steffen, W. et al., 2018: Trajectories of the Earth System in the Anthropocene. ''Proceedings of the National Academy of Sciences'' , '''115(33)''' , 8252–8259, doi: . <div id="Steinman--2015"></div> Steinman, B.A., M.E. Mann, and S.K. Miller, 2015: Atlantic and Pacific multidecadal oscillations and Northern Hemisphere temperatures. ''Science'' , '''347(6225)''' , 988–991, doi: . <div id="Steptoe--2016"></div> Steptoe, H., L.J. Wilcox, and E.J. Highwood, 2016: Is there a robust effect of anthropogenic aerosols on the Southern Annular Mode? ''Journal of Geophysical Research: Atmospheres'' , '''121(17)''' , 10,029–10,042, doi: . <div id="Stevenson--2016"></div> Stevenson, S., B. Otto-Bliesner, J. Fasullo, and E. Brady, 2016: “El Niño Like” hydroclimate responses to last millennium volcanic eruptions. ''Journal of Climate'' , '''29(8)''' , 2907–2921, doi: . <div id="Stevenson--2021"></div> Stevenson, S., A.T. Wittenberg, J. Fasullo, S. Coats, and B. Otto-Bliesner, 2021: Understanding Diverse Model Projections of Future Extreme El Niño. ''Journal of Climate'' , '''34(2)''' , 449–464, doi: . <div id="Stjern--2018"></div> Stjern, C.W. et al., 2018: Response to marine cloud brightening in a multi-model ensemble. ''Atmospheric Chemistry and Physics'' , '''18(2)''' , 621–634, doi: . <div id="Stjern--2019"></div> Stjern, C.W. et al., 2019: Arctic Amplification Response to Individual Climate Drivers. ''Journal of Geophysical Research: Atmospheres'' , '''124(13)''' , 6698–6717, doi: . <div id="Stohl--2015"></div> Stohl, A. et al., 2015: Evaluating the climate and air quality impacts of short-lived pollutants. ''Atmospheric Chemistry and Physics'' , '''15(18)''' , 10529–10566, doi: . <div id="Stolpe--2018"></div> Stolpe, M.B., I. Medhaug, J. Sedláček, and R. Knutti, 2018: Multidecadal Variability in Global Surface Temperatures Related to the Atlantic Meridional Overturning Circulation. ''Journal of Climate'' , '''31(7)''' , 2889–2906, doi: . <div id="Storelvmo--2014"></div> Storelvmo, T. and N. Herger, 2014: Cirrus cloud susceptibility to the injection of ice nuclei in the upper troposphere. ''Journal of Geophysical Research: Atmospheres'' , '''119(5)''' , 2375–2389, doi: . <div id="Storelvmo--2013"></div> Storelvmo, T. et al., 2013: Cirrus cloud seeding has potential to cool climate. ''Geophysical Research Letters'' , '''40(1)''' , 178–182, doi: . <div id="Stott--2013"></div> Stott, P., P. Good, G. Jones, N. Gillett, and E. Hawkins, 2013: The upper end of climate model temperature projections is inconsistent with past warming. ''Environmental Research Letters'' , '''8(1)''' , 014024, doi: . <div id="Stroeve--2015"></div> Stroeve, J. and D. [[#Notz--2015|Notz, 2015]] : Insights on past and future sea-ice evolution from combining observations and models. ''Global and Planetary Change'' , '''135''' , 119–132, doi: . <div id="Stroeve--2014"></div> Stroeve, J., A. Barrett, M. Serreze, and A. Schweiger, 2014: Using records from submarine, aircraft and satellites to evaluate climate model simulations of Arctic sea ice thickness. ''The Cryosphere'' , '''8(5)''' , 1839–1854, doi: . <div id="Strommen--2019"></div> Strommen, K. and T.N. Palmer, 2019: Signal and noise in regime systems: A hypothesis on the predictability of the North Atlantic Oscillation. ''Quarterly Journal of the Royal Meteorological Society'' , '''145(718)''' , 147–163, doi: . <div id="Strommen--2019"></div> Strommen, K., P.A.G. Watson, and T.N. Palmer, 2019: The Impact of a Stochastic Parameterization Scheme on Climate Sensitivity in EC-Earth. ''Journal of Geophysical Research: Atmospheres'' , '''124(23)''' , 12726–12740, doi: . <div id="Strømmen--2018"></div> Strømmen, K., H.M. Christensen, J. Berner, and T.N. Palmer, 2018: The impact of stochastic parametrisations on the representation of the Asian summer monsoon. ''Climate Dynamics'' , '''50(5–6)''' , 2269–2282, doi: . <div id="Stuart--2013"></div> Stuart, G.S. et al., 2013: Reduced efficacy of marine cloud brightening geoengineering due to in-plume aerosol coagulation: parameterization and global implications. ''Atmospheric Chemistry and Physics'' , '''13(20)''' , 10385–10396, doi: . <div id="Stuecker--2017"></div> Stuecker, M.F. et al., 2017: Revisiting ENSO/Indian Ocean Dipole phase relationships. ''Geophysical Research Letters'' , '''44(5)''' , 2481–2492, doi: . <div id="Stuecker--2018"></div> Stuecker, M.F. et al., 2018: Polar amplification dominated by local forcing and feedbacks. ''Nature Climate Change'' , '''8(12)''' , 1076–1081, doi: . <div id="Suárez-Gutiérrez--2017"></div> Suárez-Gutiérrez, L., C. Li, P.W. Thorne, and J. Marotzke, 2017: Internal variability in simulated and observed tropical tropospheric temperature trends. ''Geophysical Research Letters'' , '''44''' , 5709–5719, doi: . <div id="Suárez-Gutiérrez--2018"></div> Suárez-Gutiérrez, L., C. Li, W.A. Müller, and J. Marotzke, 2018: Internal variability in European summer temperatures at 1.5°C and 2°C of global warming. ''Environmental Research Letters'' , '''13(6)''' , 064026, doi: . <div id="Sun--2018"></div> Sun, L., M. Alexander, and C. Deser, 2018: Evolution of the Global Coupled Climate Response to Arctic Sea Ice Loss during 1990–2090 and Its Contribution to Climate Change. ''Journal of Climate'' , '''31(19)''' , 7823–7843, doi: . <div id="Sun--2019"></div> Sun, W. et al., 2019: A “La Niña-like” state occurring in the second year after large tropical volcanic eruptions during the past 1500 years. ''Climate Dynamics'' , '''52(12)''' , 7495–7509, doi: . <div id="Sutton--2018"></div> Sutton, R.T., 2018: ESD Ideas: a simple proposal to improve the contribution of IPCC WGI to the assessment and communication of climate change risks. ''Earth System Dynamics'' , '''9(4)''' , 1155–1158, doi: . <div id="Sutton--2007"></div> Sutton, R.T., B. Dong, and J.M. Gregory, 2007: Land/sea warming ratio in response to climate change: IPCC AR4 model results and comparison with observations. ''Geophysical Research Letters'' , '''34(2)''' , L02701, doi: . <div id="Svendsen--2014"></div> Svendsen, L., S. Hetzinger, N. Keenlyside, and Y. Gao, 2014: Marine-based multiproxy reconstruction of Atlantic multidecadal variability. ''Geophysical Research Letters'' , '''41(4)''' , 1295–1300, doi: . <div id="Swann--2016"></div> Swann, A.L.S., F.M. Hoffman, C.D. Koven, and J.T. Randerson, 2016: Plant responses to increasing CO <sub>2</sub> reduce estimates of climate impacts on drought severity. ''Proceedings of the National Academy of Sciences'' , '''113(36)''' , 10019–10024, doi: . <div id="Swart--2019"></div> Swart, N.C. et al., 2019: The Canadian Earth System Model version 5 (CanESM5.0.3). ''Geoscientific Model Development'' , '''12(11)''' , 4823–4873, doi: . <div id="Swingedouw--2015"></div> Swingedouw, D. et al., 2015: Bidecadal North Atlantic ocean circulation variability controlled by timing of volcanic eruptions. ''Nature Communications'' , '''6(1)''' , 6545, doi: . <div id="Swingedouw--2017"></div> Swingedouw, D. et al., 2017: Impact of explosive volcanic eruptions on the main climate variability modes. ''Global and Planetary Change'' , '''150''' , 24–45, doi: . <div id="Tachiiri--2019"></div> Tachiiri, K., D. Silva Herran, X. Su, and M. Kawamiya, 2019: Effect on the Earth system of realizing a 1.5°C warming climate target after overshooting to the 2°C level. ''Environmental Research Letters'' , '''14(12)''' , 124063, doi: . <div id="Tamarin-Brodsky--2017"></div> Tamarin-Brodsky, T. and Y. Kaspi, 2017: Enhanced poleward propagation of storms under climate change. ''Nature Geoscience'' , '''10(12)''' , 908–913, doi: . <div id="Tamarin-Brodsky--2020"></div> Tamarin-Brodsky, T., K. Hodges, B.J. Hoskins, and T.G. Shepherd, 2020: Changes in Northern Hemisphere temperature variability shaped by regional warming patterns. ''Nature Geoscience'' , '''13(6)''' , 414–421, doi: . <div id="Taylor--2012"></div> Taylor, K.E., R.J. Stouffer, and G.A. Meehl, 2012: An Overview of CMIP5 and the Experiment Design. ''Bulletin of the American Meteorological Society'' , '''93(4)''' , 485–498, doi: . <div id="Tebaldi--2007"></div> Tebaldi, C. and R. Knutti, 2007: The use of the multi-model ensemble in probabilistic climate projections. ''Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences'' , '''365(1857)''' , 2053–2075, doi: . <div id="Tebaldi--2013"></div> Tebaldi, C. and P. Friedlingstein, 2013: Delayed detection of climate mitigation benefits due to climate inertia and variability. ''Proceedings of the National Academy of Sciences'' , '''110(43)''' , 17229–17234, doi: . <div id="Tebaldi--2014"></div> Tebaldi, C. and J.M. Arblaster, 2014: Pattern scaling: Its strengths and limitations, and an update on the latest model simulations. ''Climatic Change'' , '''122(3)''' , 459–471, doi: . <div id="Tebaldi--2018"></div> Tebaldi, C. and R. Knutti, 2018: Evaluating the accuracy of climate change pattern emulation for low warming targets. ''Environmental Research Letters'' , '''13(5)''' , 055006, doi: . <div id="Tebaldi--2018"></div> Tebaldi, C. and M.F. Wehner, 2018: Benefits of mitigation for future heat extremes under RCP4.5 compared to RCP8.5. ''Climatic Change'' , '''146(3–4)''' , 349–361, doi: . <div id="Tebaldi--2011"></div> Tebaldi, C., J.M. Arblaster, and R. Knutti, 2011: Mapping model agreement on future climate projections. ''Geophysical Research Letters'' , '''38(23)''' , L23701, doi: . <div id="Tebaldi--2015"></div> Tebaldi, C., B. O’Neill, and J.-F. Lamarque, 2015: Sensitivity of regional climate to global temperature and forcing. ''Environmental Research Letters'' , '''10(7)''' , 74001, doi: . <div id="Tebaldi--2021"></div> Tebaldi, C. et al., 2021: Climate model projections from the Scenario Model Intercomparison Project (ScenarioMIP) of CMIP6. ''Earth System Dynamics'' , '''12(1)''' , 253–293, doi: . <div id="Teng--2017"></div> Teng, H., G.A. Meehl, G. Branstator, S. Yeager, and A. Karspeck, 2017: Initialization Shock in CCSM4 Decadal Prediction Experiments. ''Past Global Changes Magazine'' , '''25(1)''' , 41–46, doi: . <div id="Terhaar--2020"></div> Terhaar, J., L. Kwiatkowski, and L. Bopp, 2020: Emergent constraint on Arctic Ocean acidification in the twenty-first century. ''Nature'' , '''582(7812)''' , 379–383, doi: . <div id="The Royal Society--2009"></div> [[#The%20Royal%20Society--2009|The Royal Society, 2009]] : ''Geoengineering the climate: science, governance and uncertainty'' . RS Policy document 10/09, The Royal Society, London, UK, 82 pp., . <div id="Thoma--2015a"></div> Thoma, M., R. Gerdes, R.J. Greatbatch, and H. Ding, 2015a: Partially coupled spin-up of the MPI-ESM: implementation and first results. ''Geoscientific Model Development'' , '''8(1)''' , 51–68, doi: . <div id="Thoma--2015b"></div> Thoma, M., R.J. Greatbatch, C. Kadow, and R. Gerdes, 2015b: Decadal hindcasts initialized using observed surface wind stress: Evaluation and prediction out to 2024. ''Geophysical Research Letters'' , '''42(15)''' , 6454–6461, doi: . <div id="Thompson--2015"></div> Thompson, D.W.J., E.A. Barnes, C. Deser, W.E. Foust, and A.S. Phillips, 2015: Quantifying the Role of Internal Climate Variability in Future Climate Trends. ''Journal of Climate'' , '''28(16)''' , 6443–6456, doi: . <div id="Tilmes--2016"></div> Tilmes, S., B.M. Sanderson, and B.C. O’Neill, 2016: Climate impacts of geoengineering in a delayed mitigation scenario. ''Geophysical Research Letters'' , '''43(15)''' , 8222–8229, doi: . <div id="Tilmes--2013"></div> Tilmes, S. et al., 2013: The hydrological impact of geoengineering in the Geoengineering Model Intercomparison Project (GeoMIP). ''Journal of Geophysical Research: Atmospheres'' , '''118(19)''' , 11036–11058, doi: . <div id="Tilmes--2017"></div> Tilmes, S. et al., 2017: Sensitivity of aerosol distribution and climate response to stratospheric SO <sub>2</sub> injection locations. ''Journal of Geophysical Research: Atmospheres'' , '''122(23)''' , 12591–12615, doi: . <div id="Tilmes--2018a"></div> Tilmes, S. et al., 2018a: CESM1(WACCM) Stratospheric Aerosol Geoengineering Large Ensemble Project. ''Bulletin of the American Meteorological Society'' , '''99(11)''' , 2361–2371, doi: . <div id="Tilmes--2018b"></div> Tilmes, S. et al., 2018b: Effects of Different Stratospheric SO <sub>2</sub> injection Altitudes on Stratospheric Chemistry and Dynamics. ''Journal of Geophysical Research: Atmospheres'' , '''123(9)''' , 4654–4673, doi: . <div id="Tilmes--2020"></div> Tilmes, S. et al., 2020: Reaching 1.5 and 2.0°C global surface temperature targets using stratospheric aerosol geoengineering. ''Earth System Dynamics'' , '''11(3)''' , 579–601, doi: . <div id="Timmermann--2018"></div> Timmermann, A. et al., 2018: El Niño-Southern Oscillation complexity. ''Nature'' , '''559(7715)''' , 535–545, doi: . <div id="Timmreck--2016"></div> Timmreck, C., H. Pohlmann, S. Illing, and C. Kadow, 2016: The impact of stratospheric volcanic aerosol on decadal-scale climate predictions. ''Geophysical Research Letters'' , '''43(2)''' , 834–842, doi: . <div id="Tjiputra--2016"></div> Tjiputra, J.F., A. Grini, and H. Lee, 2016: Impact of idealized future stratospheric aerosol injection on the large-scale ocean and land carbon cycles. ''Journal of Geophysical Research: Biogeosciences'' , '''121(1)''' , 2–27, doi: . <div id="Tokarska--2015"></div> Tokarska, K.B. and K. Zickfeld, 2015: The effectiveness of net negative carbon dioxide emissions in reversing anthropogenic climate change. ''Environmental Research Letters'' , '''10(9)''' , 094013, doi: . <div id="Tokarska--2019"></div> Tokarska, K.B., K. Zickfeld, and J. Rogelj, 2019: Path Independence of Carbon Budgets When Meeting a Stringent Global Mean Temperature Target After an Overshoot. ''Earth’s Future'' , '''7(12)''' , 1283–1295, doi: . <div id="Tokarska--2020"></div> Tokarska, K.B. et al., 2020: Past warming trend constrains future warming in CMIP6 models. ''Science Advances'' , '''6(12)''' , eaaz9549, doi: . <div id="Toll--2019"></div> Toll, V., M. Christensen, J. Quaas, and N. Bellouin, 2019: Weak average liquid-cloud-water response to anthropogenic aerosols. ''Nature'' , '''572(7767)''' , 51–55, doi: . <div id="Toohey--2016"></div> Toohey, M., K. Krüger, M. Sigl, F. Stordal, and H. Svensen, 2016: Climatic and societal impacts of a volcanic double event at the dawn of the Middle Ages. ''Climatic Change'' , '''136(3–4)''' , 401–412, doi: . <div id="Tsutsui--2006"></div> Tsutsui, J. et al., 2006: Long-term climate response to stabilized and overshoot anthropogenic forcings beyond the twenty-first century. ''Climate Dynamics'' , '''28(2–3)''' , 199–214, doi: . <div id="Tung--2019"></div> Tung, K.-K., X. Chen, J. Zhou, and K.-F. Li, 2019: Interdecadal variability in pan-Pacific and global SST, revisited. ''Climate Dynamics'' , '''52(3)''' , 2145–2157, doi: . <div id="UNFCCC--2016"></div> [[#UNFCCC--2016|UNFCCC, 2016]] : Decision 1/CP.21: Adoption of the Paris Agreement. In: ''Report of the Conference of the Parties on its twenty-first session, held in Paris from 30 November to 13 December 2015. Addendum: Part two: Action taken by the Conference of the Parties at its twenty-first session'' . FCCC/CP/2015/10/Add.1, United Nations Framework Convention on Climate Change (UNFCCC), pp. 1–36, . <div id="Valdes--2011"></div> Valdes, P., 2011: Built for stability. ''Nature Geoscience'' , '''4(7)''' , 414–416, doi: . <div id="Vallis--2015"></div> Vallis, G.K., P. Zurita-Gotor, C. Cairns, and J. Kidston, 2015: Response of the large-scale structure of the atmosphere to global warming. ''Quarterly Journal of the Royal Meteorological Society'' , '''141(690)''' , 1479–1501, doi: . <div id="van Oldenborgh--2012"></div> van Oldenborgh, G.J., F.J. Doblas-Reyes, B. Wouters, and W. Hazeleger, 2012: Decadal prediction skill in a multi-model ensemble. ''Climate Dynamics'' , '''38(7–8)''' , 1263–1280, doi: . <div id="van Vuuren--2011"></div> van Vuuren, D.P. et al., 2011: The representative concentration pathways: an overview. ''Climatic Change'' , '''109(1–2)''' , 5–31, doi: . <div id="van Vuuren--2016"></div> van Vuuren, D.P. et al., 2016: Carbon budgets and energy transition pathways. ''Environmental Research Letters'' , '''11(7)''' , 75002, doi: . <div id="Vecchi--2017"></div> Vecchi, G.A., T.L. Delworth, and B. Booth, 2017: Origins of Atlantic decadal swings. ''Nature'' , '''548(7667)''' , 284–285, doi: . <div id="Vecchi--2014"></div> Vecchi, G.A. et al., 2014: On the Seasonal Forecasting of Regional Tropical Cyclone Activity. ''Journal of Climate'' , '''27(21)''' , 7994–8016, doi: . <div id="Vega-Westhoff--2017"></div> Vega-Westhoff, B. and R.L. Sriver, 2017: Analysis of ENSO’s response to unforced variability and anthropogenic forcing using CESM. ''Scientific Reports'' , '''7(1)''' , 18047, doi: . <div id="Vial--2013"></div> Vial, J., J.-L. Dufresne, and S. Bony, 2013: On the interpretation of inter-model spread in CMIP5 climate sensitivity estimates. ''Climate Dynamics'' , '''41(''' '''11–1''' '''2)''' , 3339–3362, doi: . <div id="Vicente-Serrano--2018"></div> Vicente-Serrano, S.M.M. et al., 2018: Recent changes of relative humidity: regional connections with land and ocean processes. ''Earth System Dynamics'' , '''9(2)''' , 915–937, doi: . <div id="Villamayor--2018"></div> Villamayor, J., T. Ambrizzi, and E. Mohino, 2018: Influence of decadal sea surface temperature variability on northern Brazil rainfall in CMIP5 simulations. ''Climate Dynamics'' , '''51(1)''' , 563–579, doi: . <div id="Visioni--2017"></div> Visioni, D., G. Pitari, and V. Aquila, 2017: Sulfate geoengineering: a review of the factors controlling the needed injection of sulfur dioxide. ''Atmospheric Chemistry and Physics'' , '''17(6)''' , 3879–3889, doi: . <div id="Visioni--2018"></div> Visioni, D., G. Pitari, G. di Genova, S. Tilmes, and I. Cionni, 2018: Upper tropospheric ice sensitivity to sulfate geoengineering. ''Atmospheric Chemistry and Physics'' , '''18(20)''' , 14867–14887, doi: . <div id="Visioni--2020a"></div> Visioni, D. et al., 2020a: Reduced Poleward Transport Due to Stratospheric Heating Under Stratospheric Aerosols Geoengineering. ''Geophysical Research Letters'' , '''47(17)''' , e2020GL089470, doi: . <div id="Visioni--2020b"></div> Visioni, D. et al., 2020b: Seasonally Modulated Stratospheric Aerosol Geoengineering Alters the Climate Outcomes. ''Geophysical Research Letters'' , '''47(12)''' , e2020GL088337, doi: . <div id="Visioni--2020c"></div> Visioni, D. et al., 2020c: What goes up must come down: impacts of deposition in a sulfate geoengineering scenario. ''Environmental Research Letters'' , '''15(9)''' , 094063, doi: . <div id="Vogel--2017"></div> Vogel, M.M. et al., 2017: Regional amplification of projected changes in extreme temperatures strongly controlled by soil moisture–temperature feedbacks. ''Geophysical Research Letters'' , '''44(3)''' , 1511–1519, doi: . <div id="Voigt--2015"></div> Voigt, A. and T.A. Shaw, 2015: Circulation response to warming shaped by radiative changes of clouds and water vapour. ''Nature Geoscience'' , '''8(2)''' , 102–106, doi: . <div id="Voigt--2016"></div> Voigt, A. and T.A. Shaw, 2016: Impact of regional atmospheric cloud radiative changes on shifts of the extratropical jet stream in response to global warming. ''Journal of Climate'' , '''29(23)''' , 8399–8421, doi: . <div id="Voigt--2019"></div> Voigt, A., N. Albern, and G. Papavasileiou, 2019: The atmospheric pathway of the cloud-radiative impact on the circulation response to global warming: Important and uncertain. ''Journal of Climate'' , '''32(10)''' , 3051–3067, doi: . <div id="Voigt--2017"></div> Voigt, A. et al., 2017: Fast and slow shifts of the zonal-mean intertropical convergence zone in response to an idealized anthropogenic aerosol. ''Journal of Advances in Modeling Earth Systems'' , '''9(2)''' , 870–892, doi: . <div id="von Trentini--2020"></div> von Trentini, F., E.E. Aalbers, E.M. Fischer, and R. Ludwig, 2020: Comparing interannual variability in three regional single-model initial-condition large ensembles (SMILEs) over Europe. ''Earth System Dynamics'' , '''11(4)''' , 1013–1031, doi: . <div id="Waisman--2019"></div> Waisman, H., H. De Coninck, and J. Rogelj, 2019: Key technological enablers for ambitious climate goals: insights from the IPCC special report on global warming of 1.5°C. ''Environmental Research Letters'' , '''14(11)''' , 111001, doi: . <div id="Wang--2008"></div> Wang, B. and Q. Ding, 2008: Global monsoon: Dominant mode of annual variation in the tropics. ''Dynamics of Atmospheres and Oceans'' , '''44(3–4)''' , 165–183, doi: . <div id="Wang--2020"></div> Wang, B., C. Jin, and J. Liu, 2020: Understanding Future Change of Global Monsoons Projected by CMIP6 Models. ''Journal of Climate'' , '''33(15)''' , 6471–6489, doi: . <div id="Wang--2013a"></div> Wang, B. et al., 2013a: Northern Hemisphere summer monsoon intensified by mega-El Niño/southern oscillation and Atlantic multidecadal oscillation. ''Proceedings of the National Academy of Sciences'' , '''110(14)''' , 5347–5352, doi: . <div id="Wang--2013b"></div> Wang, B. et al., 2013b: Preliminary evaluations of FGOALS-g2 for decadal predictions. ''Advances in Atmospheric Sciences'' , '''30(3)''' , 674–683, doi: . <div id="Wang--2021"></div> Wang, B. et al., 2021: Monsoons Climate Change Assessment. ''Bulletin of the American Meteorological Society'' , '''102(1)''' , E1–E19, doi: . <div id="Wang--2014"></div> Wang, G., W. Cai, and A. Purich, 2014: Trends in Southern Hemisphere wind-driven circulation in CMIP5 models over the 21st century: Ozone recovery versus greenhouse forcing. ''Journal of Geophysical Research: Oceans'' , '''119(5)''' , 2974–2986, doi: . <div id="Wang--2017a"></div> Wang, J., H.-M. Kim, and E.K.M. [[#Chang--2017|Chang, 2017]] a: Changes in Northern Hemisphere Winter Storm Tracks under the Background of Arctic Amplification. ''Journal of Climate'' , '''30(10)''' , 3705–3724, doi: . <div id="Wang--2017b"></div> Wang, J. et al., 2017b: Internal and external forcing of multidecadal Atlantic climate variability over the past 1,200 years. ''Nature Geoscience'' , '''10(7)''' , 512–517, doi: . <div id="Wang--2017"></div> Wang, P.X. et al., 2017: The global monsoon across time scales: Mechanisms and outstanding issues. ''Earth-Science Reviews'' , '''174''' , 84–121, doi: . <div id="Wang--2016"></div> Wang, Y., G.J. Zhang, and G.C. Craig, 2016: Stochastic convective parameterization improving the simulation of tropical precipitation variability in the NCAR CAM5. ''Geophysical Research Letters'' , '''43(12)''' , 6612–6619, doi: . <div id="Wang--2018"></div> Wang, Y. et al., 2018: Elucidating the Role of Anthropogenic Aerosols in Arctic Sea Ice Variations. ''Journal of Climate'' , '''31(1)''' , 99–114, doi: . <div id="Watanabe--2014"></div> Watanabe, M., Y. Kamae, and M. Kimoto, 2014: Robust increase of the equatorial Pacific rainfall and its variability in a warmed climate. ''Geophysical Research Letters'' , '''41(9)''' , 3227–3232, doi: . <div id="Watson--2017"></div> Watson, P.A.G. et al., 2017: The impact of stochastic physics on tropical rainfall variability in global climate models on daily to weekly time scales. ''Journal of Geophysical Research: Atmospheres'' , '''122(11)''' , 5738–5762, doi: . <div id="Weigel--2010"></div> Weigel, A.P., R. Knutti, M.A. Liniger, and C. Appenzeller, 2010: Risks of Model Weighting in Multimodel Climate Projections. ''Journal of Climate'' , '''23(15)''' , 4175–4191, doi: . <div id="Weijer--2020"></div> Weijer, W., W. Cheng, O.A. Garuba, A. Hu, and B.T. Nadiga, 2020: CMIP6 Models Predict Significant 21st Century Decline of the Atlantic Meridional Overturning Circulation. ''Geophysical Research Letters'' , '''47''' , e2019GL086075, doi: . <div id="Weisenstein--2015"></div> Weisenstein, D., D. Keith, and J. Dykema, 2015: Solar geoengineering using solid aerosol in the stratosphere. ''Atmospheric Chemistry and Physics'' , '''15''' , 11835–11859, doi: . <div id="Weisheimer--2014"></div> Weisheimer, A., S. Corti, T. Palmer, and F. Vitart, 2014: Addressing model error through atmospheric stochastic physical parametrizations: impact on the coupled ECMWF seasonal forecasting system. ''Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences'' , '''372(2018)''' , 20130290, doi: . <div id="Weiss--2014"></div> Weiss, M. et al., 2014: Contribution of Dynamic Vegetation Phenology to Decadal Climate Predictability. ''Journal of Climate'' , '''27(22)''' , 8563–8577, doi: . <div id="Wen--2018"></div> Wen, Q., J. Yao, K. Döös, and H. Yang, 2018: Decoding Hosing and Heating Effects on Global Temperature and Meridional Circulations in a Warming Climate. ''Journal of Climate'' , '''31(23)''' , 9605–9623, doi: . <div id="Wengel--2018"></div> Wengel, C., D. Dommenget, M. Latif, T. Bayr, and A. Vijayeta, 2018: What Controls ENSO-Amplitude Diversity in Climate Models? ''Geophysical Research Letters'' , '''45(4)''' , 1989–1996, doi: . <div id="Wilcox--2020"></div> Wilcox, L.J. et al., 2020: Accelerated increases in global and Asian summer monsoon precipitation from future aerosol reductions. ''Atmospheric Chemistry and Physics'' , '''20(20)''' , 11955–11977, doi: . <div id="Williams--2020"></div> Williams, R.G., P. Ceppi, and A. Katavouta, 2020: Controls of the transient climate response to emissions by physical feedbacks, heat uptake and carbon cycling. ''Environmental Research Letters'' , '''15(9)''' , 940–941, doi: . <div id="Williams--2017"></div> Williams, R.G., V. Roussenov, T.L. Frölicher, and P. Goodwin, 2017: Drivers of Continued Surface Warming After Cessation of Carbon Emissions. ''Geophysical Research Letters'' , '''44(20)''' , 10633–10642, doi: . <div id="Willison--2015"></div> Willison, J., W.A. Robinson, and G.M. Lackmann, 2015: North Atlantic Storm-Track Sensitivity to Warming Increases with Model Resolution. ''Journal of Climate'' , '''28(11)''' , 4513–4524, doi: . <div id="Wills--2019"></div> Wills, R.C.J., K.C. Armour, D.S. Battisti, and D.L. Hartmann, 2019: Ocean–Atmosphere Dynamical Coupling Fundamental to the Atlantic Multidecadal Oscillation. ''Journal of Climate'' , '''32(1)''' , 251–272, doi: . <div id="Winton--2006"></div> Winton, M., 2006: Amplified Arctic climate change: What does surface albedo feedback have to do with it? ''Geophysical Research Letters'' , '''33(3)''' , L03701, doi: . <div id="Wittenberg--2009"></div> Wittenberg, A.T., 2009: Are historical records sufficient to constrain ENSO simulations? ''Geophysical Research Letters'' , '''36(12)''' , L12702, doi: . <div id="WMO--2011"></div> [[#WMO--2011|WMO, 2011]] : ''Scientific Assessment of Ozone Depletion: 2010'' . Global Ozone Research and Monitoring Project – Report No. 52, World Meteorological Organization (WMO), Geneva, Switzerland, 516 pp., . <div id="WMO--2014"></div> [[#WMO--2014|WMO, 2014]] : ''Scientific Assessment of Ozone Depletion: 2014'' . Global Ozone Research and Monitoring Project – Report No. 55, World Meteorological Organization (WMO), Geneva, Switzerland, 416 pp., . <div id="WMO--2018"></div> [[#WMO--2018|WMO, 2018]] : ''Scientific Assessment of Ozone Depletion: 2018'' . Global Ozone Research and Monitoring Project – Report No. 58, World Meteorological Organization (WMO), Geneva, Switzerland, 588 pp., . <div id="Wobus--2016"></div> Wobus, C., M. Flanner, M.C. Sarofim, M.C.P. Moura, and S.J. Smith, 2016: Future Arctic temperature change resulting from a range of aerosol emissions scenarios. ''Earth’s Future'' , '''4(6)''' , 270–281, doi: . <div id="Wood--2020"></div> Wood, T., C.M. McKenna, A. Chrysanthou, and A.C. Maycock, 2020: Role of sea surface temperature patterns for the Southern Hemisphere jet stream response to CO <sub>2</sub> forcing. ''Environmental Research Letters'' , '''16(1)''' , 014020, doi: . <div id="Woods--2016"></div> Woods, C. and R. Caballero, 2016: The Role of Moist Intrusions in Winter Arctic Warming and Sea Ice Decline. ''Journal of Climate'' , '''29(12)''' , 4473–4485, doi: . <div id="Woollings--2018"></div> Woollings, T. et al., 2018: Blocking and its Response to Climate Change. ''Current Climate Change Reports'' , '''4(3)''' , 287–300, doi: . <div id="Wouters--2013"></div> Wouters, B., W. Hazeleger, S. Drijfhout, G.J. Oldenborgh, and V. Guemas, 2013: Multiyear predictability of the North Atlantic subpolar gyre. ''Geophysical Research Letters'' , '''40(12)''' , 3080–3084, doi: . <div id="Wu--2019"></div> Wu, B., T. Zhou, C. Li, W.A. Müller, and J. Lin, 2019: Improved decadal prediction of Northern-Hemisphere summer land temperature. ''Climate Dynamics'' , '''53(3)''' , 1357–1369, doi: . <div id="Wu--2010"></div> Wu, P., R. Wood, J. Ridley, and J. Lowe, 2010: Temporary acceleration of the hydrological cycle in response to a CO <sub>2</sub> rampdown. ''Geophysical Research Letters'' , '''37(12)''' , L12705, doi: . <div id="Wyser--2020"></div> Wyser, K., E. Kjellström, T. Koenigk, H. Martins, and R. Döscher, 2020: Warmer climate projections in EC-Earth3-Veg: The role of changes in the greenhouse gas concentrations from CMIP5 to CMIP6. ''Environmental Research Letters'' , '''15(5)''' , 054020, doi: . <div id="Xia--2017"></div> Xia, L., P.J. Nowack, S. Tilmes, and A. Robock, 2017: Impacts of stratospheric sulfate geoengineering on tropospheric ozone. ''Atmospheric Chemistry and Physics'' , '''17(19)''' , 11913–11928, doi: . <div id="Xie--2013"></div> Xie, S.-P., B. Lu, and B. Xiang, 2013: Similar spatial patterns of climate responses to aerosol and greenhouse gas changes. ''Nature Geoscience'' , '''6(10)''' , 828–832, doi: . <div id="Xie--2009"></div> Xie, S.-P. et al., 2009: Indian Ocean Capacitor Effect on Indo–Western Pacific Climate during the Summer following El Niño. ''Journal of Climate'' , '''22(3)''' , 730–747, doi: . <div id="Xie--2015"></div> Xie, S.-P. et al., 2015: Towards predictive understanding of regional climate change. ''Nature Climate Change'' , '''5(10)''' , 921–930, doi: . <div id="Xu--2017"></div> Xu, Y. and A. Hu, 2017: How Would the Twenty-First-Century Warming Influence Pacific Decadal Variability and Its Connection to North American Rainfall: Assessment Based on a Revised Procedure for the IPO/PDO. ''Journal of Climate'' , '''31(4)''' , 1547–1563, doi: . <div id="Xu--2017"></div> Xu, Y. and V. Ramanathan, 2017: Well below 2°C: Mitigation strategies for avoiding dangerous to catastrophic climate changes. ''Proceedings of the National Academy of Sciences'' , '''114(39)''' , 10315–10323, doi: . <div id="Yang--2019"></div> Yang, C., H.M. Christensen, S. Corti, J. von Hardenberg, and P. Davini, 2019: The impact of stochastic physics on the El Niño Southern Oscillation in the EC-Earth coupled model. ''Climate Dynamics'' , '''53(5–6)''' , 2843–2859, doi: . <div id="Yang--2018"></div> Yang, J. and C. Xiao, 2018: The evolution and volcanic forcing of the southern annular mode during the past 300 years. ''International Journal of Climatology'' , '''38(4)''' , 1706–1717, doi: . <div id="Yeager--2017"></div> Yeager, S.G. and J.I. Robson, 2017: Recent Progress in Understanding and Predicting Atlantic Decadal Climate Variability. ''Current Climate Change Reports'' , '''3(2)''' , 112–127, doi: . <div id="Yeager--2015"></div> Yeager, S.G., A.R. Karspeck, and G. Danabasoglu, 2015: Predicted slowdown in the rate of Atlantic sea ice loss. ''Geophysical Research Letters'' , '''42(24)''' , 10704–10713, doi: . <div id="Yeager--2018"></div> Yeager, S.G. et al., 2018: Predicting Near-Term Changes in the Earth System: A Large Ensemble of Initialized Decadal Prediction Simulations Using the Community Earth System Model. ''Bulletin of the American Meteorological Society'' , '''99(9)''' , 1867–1886, doi: . <div id="Yeh--2018"></div> Yeh, S.-W. et al., 2018: ENSO Atmospheric Teleconnections and Their Response to Greenhouse Gas Forcing. ''Reviews of Geophysics'' , '''56(1)''' , 185–206, doi: . <div id="Yettella--2017"></div> Yettella, V. and J.E. Kay, 2017: How will precipitation change in extratropical cyclones as the planet warms? Insights from a large initial condition climate model ensemble. ''Climate Dynamics'' , '''49(5–6)''' , 1765–1781, doi: . <div id="Young--2014"></div> Young, P.J., S.M. Davis, B. Hassler, S. Solomon, and K.H. Rosenlof, 2014: Modeling the climate impact of Southern Hemisphere ozone depletion: The importance of the ozone data set. ''Geophysical Research Letters'' , '''41(24)''' , 9033–9039, doi: . <div id="Yun--2021"></div> Yun, K.-S. et al., 2021: Increasing ENSO–rainfall variability due to changes in future tropical temperature–rainfall relationship. ''Communications Earth & Environment'' , '''2(1)''' , 43, doi: . <div id="Zambri--2017"></div> Zambri, B., A.N. LeGrande, A. Robock, and J. Slawinska, 2017: Northern Hemisphere winter warming and summer monsoon reduction after volcanic eruptions over the last millennium. ''Journal of Geophysical Research: Atmospheres'' , '''122(15)''' , 7971–7989, doi: . <div id="Zampieri--2019"></div> Zampieri, L. and H.F. Goessling, 2019: Sea Ice Targeted Geoengineering Can Delay Arctic Sea Ice Decline but not Global Warming. ''Earth’s Future'' , '''7(12)''' , 1296–1306, doi: . <div id="Zappa--2019"></div> Zappa, G., 2019: Regional Climate Impacts of Future Changes in the Mid-Latitude Atmospheric Circulation: a Storyline View. ''Current Climate Change Reports'' , '''5(4)''' , 358–371, doi: . <div id="Zappa--2017"></div> Zappa, G. and T.G. Shepherd, 2017: Storylines of Atmospheric Circulation Change for European Regional Climate Impact Assessment. ''Journal of Climate'' , '''30(16)''' , 6561–6577, doi: . <div id="Zappa--2015"></div> Zappa, G., B.J. Hoskins, and T.G. Shepherd, 2015: Improving Climate Change Detection through Optimal Seasonal Averaging: The Case of the North Atlantic Jet and European Precipitation. ''Journal of Climate'' , '''28(16)''' , 6381–6397, doi: . <div id="Zappa--2018"></div> Zappa, G., F. Pithan, and T.G. Shepherd, 2018: Multimodel Evidence for an Atmospheric Circulation Response to Arctic Sea Ice Loss in the CMIP5 Future Projections. ''Geophysical Research Letters'' , '''45(2)''' , 1011–1019, doi: . <div id="Zappa--2021"></div> Zappa, G., E. Bevacqua, and T.G. Shepherd, 2021: Communicating potentially large but non-robust changes in multi-model projections of future climate. ''International Journal of Climatology'' , '''41(6)''' , 3657–3669, doi: . <div id="Zarakas--2020"></div> Zarakas, C.M., A.L.S. Swann, M.M. Laguë, K.C. Armour, and J.T. Randerson, 2020: Plant Physiology Increases the Magnitude and Spread of the Transient Climate Response to CO <sub>2</sub> in CMIP6 Earth System Models. ''Journal of Climate'' , '''33(19)''' , 8561–8578, doi: . <div id="Zelinka--2020"></div> Zelinka, M.D. et al., 2020: Causes of Higher Climate Sensitivity in CMIP6 Models. ''Geophysical Research Letters'' , '''47(1)''' , e2019GL085782, doi: . <div id="Zhang--2018"></div> Zhang, H. and T.L. Delworth, 2018: Robustness of anthropogenically forced decadal precipitation changes projected for the 21st century. ''Nature Communications'' , '''9(1)''' , 1150, doi: . <div id="Zhang--2016"></div> Zhang, J., K. Zhang, J. Liu, and G. Ban-Weiss, 2016: Revisiting the climate impacts of cool roofs around the globe using an Earth system model. ''Environmental Research Letters'' , '''11(8)''' , 84014, doi: . <div id="Zhang--2016"></div> Zhang, L. and T.L. Delworth, 2016: Simulated Response of the Pacific Decadal Oscillation to Climate Change. ''Journal of Climate'' , '''29(16)''' , 5999–6018, doi: . <div id="Zhang--2019"></div> Zhang, R. et al., 2019: A Review of the Role of the Atlantic Meridional Overturning Circulation in Atlantic Multidecadal Variability and Associated Climate Impacts. ''Reviews of Geophysics'' , '''57(2)''' , 316–375, doi: . <div id="Zhang--2021"></div> Zhang, W. and T. Zhou, 2021: The Effect of Modeling Strategies on Assessments of Differential Warming Impacts of 0.5°C. ''Earth’s Future'' , '''9(4)''' , e2020EF001640, doi: . <div id="Zhang--2019"></div> Zhang, W., T. Zhou, L. Zhang, and L. Zou, 2019: Future Intensification of the Water Cycle with an Enhanced Annual Cycle over Global Land Monsoon Regions. ''Journal of Climate'' , '''32(17)''' , 5437–5452, doi: . <div id="Zhang--1997"></div> Zhang, Y., J.M. Wallace, and D.S. Battisti, 1997: ENSO-like Interdecadal Variability: 1900–93. ''Journal of Climate'' , '''10(5)''' , 1004–1020, doi: . <div id="Zhao--2017"></div> Zhao, L., Y. Yang, W. Cheng, D. Ji, and J.C. Moore, 2017: Glacier evolution in high-mountain Asia under stratospheric sulfate aerosol injection geoengineering. ''Atmospheric Chemistry and Physics'' , '''17(11)''' , 6547–6564, doi: . <div id="Zhao--2021"></div> Zhao, M., L. Cao, L. Duan, G. Bala, and K. Caldeira, 2021: Climate More Responsive to Marine Cloud Brightening Than Ocean Albedo Modification: A Model Study. ''Journal of Geophysical Research: Atmospheres'' , '''126(3)''' , e2020JD033256, doi: . <div id="Zheng--2013"></div> Zheng, F., J. Li, R.T. Clark, and H.C. Nnamchi, 2013: Simulation and Projection of the Southern Hemisphere Annular Mode in CMIP5 Models. ''Journal of Climate'' , '''26(24)''' , 9860–9879, doi: . <div id="Zheng--2018"></div> Zheng, X.-T., C. Hui, and S.-W. Yeh, 2018: Response of ENSO amplitude to global warming in CESM large ensemble: uncertainty due to internal variability. ''Climate Dynamics'' , '''50(11–12)''' , 4019–4035, doi: . <div id="Zheng--2016"></div> Zheng, X.-T., S.-P. Xie, L.-H. Lv, and Z.-Q. Zhou, 2016: Intermodel Uncertainty in ENSO Amplitude Change Tied to Pacific Ocean Warming Pattern. ''Journal of Climate'' , '''29(20)''' , 7265–7279, doi: . <div id="Zheng--2013"></div> Zheng, X.-T. et al., 2013: Indian Ocean Dipole Response to Global Warming in the CMIP5 Multimodel Ensemble. ''Journal of Climate'' , '''26(16)''' , 6067–6080, doi: . <div id="Zhou--2016"></div> Zhou, J., K.-K. Tung, and K.-F. Li, 2016: Multi-decadal variability in the Greenland ice core records obtained using intrinsic timescale decomposition. ''Climate Dynamics'' , '''47(3)''' , 739–752, doi: . <div id="Zhou--2020"></div> Zhou, T., J. Lu, W. Zhang, and Z. Chen, 2020: The Sources of Uncertainty in the Projection of Global Land Monsoon Precipitation. ''Geophysical Research Letters'' , '''47(15)''' , e2020GL088415, doi: . <div id="Zhu--2020"></div> Zhu, F., J. Emile-Geay, G.J. Hakim, J. King, and K.J. Anchukaitis, 2020: Resolving the Differences in the Simulated and Reconstructed Temperature Response to Volcanism. ''Geophysical Research Letters'' , '''47(8)''' , 1–12, doi: . <div id="Zhu--2020"></div> Zhu, J., C.J. Poulsen, and B.L. Otto-Bliesner, 2020: High climate sensitivity in CMIP6 model not supported by paleoclimate. ''Nature Climate Change'' , '''10(5)''' , 378–379, doi: . <div id="Zickfeld--2015"></div> Zickfeld, K. and T. Herrington, 2015: The time lag between a carbon dioxide emission and maximum warming increases with the size of the emission. ''Environmental Research Letters'' , '''10(3)''' , 31001, doi: . <div id="Zickfeld--2016"></div> Zickfeld, K., A.H. MacDougall, and H.D. Matthews, 2016: On the proportionality between global temperature change and cumulative CO <sub>2</sub> emissions during periods of net negative CO <sub>2</sub> emissions. ''Environmental Research Letters'' , '''11(5)''' , 055006, doi: . <div id="Zickfeld--2017"></div> Zickfeld, K., S. Solomon, and D.M. Gilford, 2017: Centuries of thermal sea-level rise due to anthropogenic emissions of short-lived greenhouse gases. ''Proceedings of the National Academy of Sciences'' , '''114(4)''' , 657–662, doi: . <div id="Zickfeld--2013"></div> Zickfeld, K. et al., 2013: Long-Term Climate Change Commitment and Reversibility: An EMIC Intercomparison. ''Journal of Climate'' , '''26(16)''' , 5782–5809, doi: . <div id="Zuo--2019a"></div> Zuo, M., T. Zhou, and W. Man, 2019a: Hydroclimate Responses over Global Monsoon Regions Following Volcanic Eruptions at Different Latitudes. ''Journal of Climate'' , '''32(14)''' , 4367–4385, doi: . <div id="Zuo--2019b"></div> Zuo, M., T. Zhou, and W. Man, 2019b: Wetter Global Arid Regions Driven by Volcanic Eruptions. ''Journal of Geophysical Research: Atmospheres'' , '''124(24)''' , 13648–13662, doi: . <div id="Zuo--2018"></div> Zuo, M., W. Man, T. Zhou, and Z. Guo, 2018: Different Impacts of Northern, Tropical, and Southern Volcanic Eruptions on the Tropical Pacific SST in the Last Millennium. ''Journal of Climate'' , '''31(17)''' , 6729–6744, doi: .
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