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1. Understanding the Cascade: Removing GCM Biases Improves Dynamically Downscaled Climate Projections

Author

Rahimi, Stefan, Huang, Lei, Norris, Jesse, Hall, Alex, Goldenson, Naomi, Risser, Mark, Feldman, Daniel R, Lebo, Zachary J, Dennis, Eli, and Thackeray, Chad

Subjects
Earth Sciences, Atmospheric Sciences, Climate Action, dynamical downscaling, regional climate, bias correction, Meteorology & Atmospheric Sciences
Abstract

Polarization surrounding bias correction (BC) in creating climate projections arises from its lack of physicality. Here, we perform and analyze 18 dynamical downscaling simulations (with and without BC) to better understand the physical impacts of BC, applied before downscaling, on regional climate output across the western United States. Without BC, downscaled precipitation is systematically and unrealistically wet biased compared to a hierarchy of observationally based datasets over the 1980–2014 period due to cascading mean-state Global Climate Model (GCM) biases: (a) overly strong lower-tropospheric lapse rates (5 K/km), (b) overly cold (2 K) tropospheric temperatures, and (c) anomalous mid-tropospheric cyclonic vorticity advection. With BC, downscaled precipitation (snow) biases are virtually eliminated (halved). Identified GCM biases are common to the broader Coupled Model Intercomparison Project ensemble. Physical effects of BC on the quality of the regionalized projections, pending an evaluation of BC's distortion of the downscaled climate response, may motivate its broader application by dynamical downscalers.

Published
2024

3. Emergent constraints on climate sensitivities

Author

Williamson, Mark S., Thackeray, Chad W., Cox, Peter M., Hall, Alex, Huntingford, Chris, and Nijsse, Femke J. M. M.

Subjects
Physics - Atmospheric and Oceanic Physics, Physics - Geophysics
Abstract

Despite major advances in climate science over the last 30 years, persistent uncertainties in projections of future climate change remain. Climate projections are produced with increasingly complex models which attempt to represent key processes in the Earth system, including atmospheric and oceanic circulations, convection, clouds, snow, sea-ice, vegetation and interactions with the carbon cycle. Uncertainties in the representation of these processes feed through into a range of projections from the many state-of-the-art climate models now being developed and used worldwide. For example, despite major improvements in climate models, the range of equilibrium global warming due to doubling carbon dioxide still spans a range of more than three. Here we review a promising way to make use of the ensemble of climate models to reduce the uncertainties in the sensitivities of the real climate system. The emergent constraint approach uses the model ensemble to identify a relationship between an uncertain aspect of the future climate and an observable variation or trend in the contemporary climate. This review summarises previous published work on emergent constraints, and discusses the huge promise and potential dangers of the approach. Most importantly, it argues that emergent constraints should be based on well-founded physical principles such as the fluctuation-dissipation theorem. It is hoped that this review will stimulate physicists to contribute to the rapidly developing field of emergent constraints on climate projections, bringing to it much needed rigour and physical insights., Comment: 39 pages, 7 figures, submitted to Reviews of Modern Physics

Published
2020
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12. An overview of the Western United States Dynamically Downscaled Dataset (WUS-D3).

Author

Rahimi, Stefan, Huang, Lei, Norris, Jesse, Hall, Alex, Goldenson, Naomi, Krantz, Will, Bass, Benjamin, Thackeray, Chad, Lin, Henry, Chen, Di, Dennis, Eli, Collins, Ethan, Lebo, Zachary J., Slinskey, Emily, Graves, Sara, Biyani, Surabhi, Wang, Bowen, and Cropper, Stephen

Subjects
CLIMATE change models, CLIMATE extremes, WILDFIRES, ATMOSPHERIC circulation, GLOBAL warming, AIR masses
Abstract

Predicting future climate change over a region of complex terrain, such as the western United States (US), remains challenging due to the low resolution of global climate models (GCMs). Yet the climate extremes of recent years in this region, such as floods, wildfires, and drought, are likely to intensify further as climate warms, underscoring the need for high-quality and high-resolution predictions. Here, we present an ensemble of dynamically downscaled simulations over the western US from 1980–2100 at 9 km grid spacing, driven by 16 latest-generation GCMs. This dataset is titled the Western US Dynamically Downscaled Dataset (WUS-D3). We describe the challenges of producing WUS-D3, including GCM selection and technical issues, and we evaluate the simulations' realism by comparing historical results to temperature and precipitation observations. The future downscaled climate change signals are shaped in physically credible ways by the regional model's more realistic coastlines and topography. (1) The mean warming signals are heavily influenced by more realistic snowpack. (2) Mean precipitation changes are often consistent with wetting on the windward side of mountain complexes, as warmer, moister air masses are uplifted orographically during precipitation events. (3) There are large fractional precipitation increases on the lee side of mountain complexes, leading to potentially significant changes in water resources and ecology in these arid landscapes. (4) Increases in precipitation extremes are generally larger than in the GCMs, driven by locally intensified atmospheric updrafts tied to sharper, more realistic gradients in topography. (5) Changes in temperature extremes are different from what is expected by a shift in mean temperature and are shaped by local atmospheric dynamics and land surface feedbacks. Because of its high resolution, comprehensiveness, and representation of relevant physical processes, this dataset presents a unique opportunity to evaluate societally relevant future changes in western US climate. [ABSTRACT FROM AUTHOR]

Published
2024
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14. An Overview of the Western United States Dynamically Downscaled Dataset (WUS-D3).

Author

Rahimi, Stefan, Lei Huang, Norris, Jesse, Hall, Alex, Goldenson, Naomi, Krantz, Will, Bass, Benjamin, Thackeray, Chad, Lin, Henry, Di Chen, Dennis, Eli, Collins, Ethan, Lebo, Zachary J., and Slinskey, Emily

Subjects
CLIMATE change models, CLIMATE extremes, WILDFIRES, ATMOSPHERIC circulation, GLOBAL warming, AIR masses
Abstract

Predicting future climate change over a region of complex terrain, such as the western United States (U.S.), remains challenging due to the low resolution of global climate models (GCMs). Yet climate extremes of recent years in this region, such as floods, wildfires, and drought, are likely to intensify further as climate warms, underscoring the need for high-quality predictions. Here, we present an ensemble of dynamically downscaled simulations over the western U.S. from 1980-2100 at 9-km grid spacing, driven by sixteen latest-generation GCMs. This dataset is titled the Western U.S. Dynamically Downscaled Dataset (WUS-D3). We describe the challenges of producing WUS-D3, including GCM selection and technical issues, and we evaluate the simulations' realism by comparing historical results to temperature and precipitation observations. The future downscaled climate change signals are shaped in physically credible ways by the regional model's more realistic coastlines and topography: (1) The mean warming signals are heavily influenced by more realistic snowpack. (2) Mean precipitation changes are often consistent with wetting on the windward side of mountain complexes, as warmer, moister air masses are uplifted orographically during precipitation events. (3) There are large fractional precipitation increases on the lee side of mountain complexes, leading to potentially significant changes in water resources and ecology in these arid landscapes. (4) Increases in precipitation extremes are generally larger than in the GCMs, driven intensified local atmospheric updrafts tied to topography. (5) Changes in temperature extremes are different from what is expected by a shift in mean temperature and are shaped by local atmospheric dynamics and land surface feedbacks. Because of its high resolution, comprehensiveness, and representation of relevant physical processes, this dataset presents a unique opportunity to evaluate societally relevant future changes in western U.S. climate. [ABSTRACT FROM AUTHOR]

Published
2023
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21. Emergent constraints on climate sensitivities

Author

Williamson, Mark S., Thackeray, Chad W., Cox, Peter M., Hall, Alex, Huntingford, Chris, Nijsse, Femke J.M.M., Williamson, Mark S., Thackeray, Chad W., Cox, Peter M., Hall, Alex, Huntingford, Chris, and Nijsse, Femke J.M.M.

Abstract

Despite major advances in climate science over the last 30 years, persistent uncertainties in projections of future climate change remain. Climate projections are produced with increasingly complex models that attempt to represent key processes in the Earth system, including atmospheric and oceanic circulations, convection, clouds, snow, sea ice, vegetation, and interactions with the carbon cycle. Uncertainties in the representation of these processes feed through into a range of projections from the many state-of-the-art climate models now being developed and used worldwide. For example, despite major improvements in climate models, the range of equilibrium global warming due to doubling carbon dioxide still spans a range of more than 3. Here a promising way to make use of the ensemble of climate models to reduce the uncertainties in the sensitivities of the real climate system is reviewed. The emergent constraint approach uses the model ensemble to identify a relationship between an uncertain aspect of the future climate and an observable variation or trend in the contemporary climate. This review summarizes previous published work on emergent constraints and discusses the promise and potential dangers of the approach. Most importantly, it argues that emergent constraints should be based on well-founded physical principles such as the fluctuation-dissipation theorem. This review will stimulate physicists to contribute to the rapidly developing field of emergent constraints on climate projections, bringing to it much needed rigor and physical insights.

Published
2021

26. ESM-SnowMIP: assessing snow models and quantifying snow-related climate feedbacks

Author

Krinner, Gerhard, Derksen, Chris, Essery, Richard, Flanner, Mark, Hagemann, Stefan, Clark, Martyn, Hall, Alex, Rott, Helmut, Brutel-Vuilmet, Claire, Kim, Hyungjun, Ménard, Cécile B., Mudryk, Lawrence, Thackeray, Chad, Wang, Libo, Arduini, Gabriele, Balsamo, Gianpaolo, Bartlett, Paul, Boike, Julia, Boone, Aaron, Chéruy, Frédérique, Colin, Jeanne, Cuntz, Matthias, Dai, Yongjiu, Decharme, Bertrand, Derry, Jeff, Ducharne, Agnès, Dutra, Emanuel, Fang, Xing, Fierz, Charles, Ghattas, Josephine, Gusev, Yeugeniy, Haverd, Vanessa, Kontu, Anna, Lafaysse, Matthieu, Law, Rachel, Lawrence, Dave, Li, Weiping, Marke, Thomas, Marks, Danny, Ménégoz, Martin, Nasonova, Olga, Nitta, Tomoko, Niwano, Masashi, Pomeroy, John, Raleigh, Mark S., Schaedler, Gerd, Semenov, Vladimir, Smirnova, Tanya G., Stacke, Tobias, Strasser, Ulrich, Svenson, Sean, Turkov, Dmitry, Wang, Tao, Wever, Nander, Yuan, Hua, Zhou, Wenyan, Zhu, Dan, SILVA (SILVA), Institut National de la Recherche Agronomique (INRA)-Université de Lorraine (UL)-AgroParisTech, World Climate Research Programme's Climate and Cryosphere (CliC) core project NERC Natural Environment Research CouncilNE/P011926/1European Space Agency Russian Science Foundation (RSF)16-17-10039Russian Foundation for Basic Research (RFBR)18-05-60216APPLICATE project European Union (EU)727862Swiss National Science Foundation (SNSF)200021E-160667European Union (EU)641816Ministry of Education, Culture, Sports, Science and Technology, Japan (MEXT)Japan Society for the Promotion of Science16H06291National Science Foundation (NSF)1543268, Laboratoire de glaciologie et géophysique de l'environnement (LGGE), Observatoire des Sciences de l'Univers de Grenoble (OSUG), Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Centre National de la Recherche Scientifique (CNRS), Climate Research Division [Toronto], Environment and Climate Change Canada, School of Geosciences Grant Institute, University of Edinburgh, Department of Climate and Space Sciences and Engineering (CLaSP), University of Michigan [Ann Arbor], University of Michigan System-University of Michigan System, Max Planck Institute for Meteorology (MPI-M), Max-Planck-Gesellschaft, Research Applications Laboratory [Boulder] (RAL), National Center for Atmospheric Research [Boulder] (NCAR), Environmental Earth Observation IT GmbH (ENVEO), Institut des Géosciences de l’Environnement (IGE), Institut de Recherche pour le Développement (IRD)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA), Institute of Industrial Science (IIS), The University of Tokyo, Milieux Environnementaux, Transferts et Interactions dans les hydrosystèmes et les Sols (METIS), École pratique des hautes études (EPHE)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Institut de Recherche pour le Développement (IRD)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), The University of Tokyo (UTokyo), École Pratique des Hautes Études (EPHE), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut de Recherche pour le Développement (IRD)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), École pratique des hautes études (EPHE), and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)

Subjects
[SDV.EE]Life Sciences [q-bio]/Ecology, environment, thermal-conductivity, arctic amplification, latitude hydrological processes, torne-kalix basin, water equivalent, Modélisation et simulation, land-surface model, intercomparison project, Earth sciences, Modeling and Simulation, [SDE]Environmental Sciences, ddc:550, albedo feedback, pilps phase-2(e), [SDU.STU.HY]Sciences of the Universe [physics]/Earth Sciences/Hydrology, Milieux et Changements globaux, sensitivity-analysis
Abstract

Krinner, Gerhard Derksen, Chris Essery, Richard Flanner, Mark Hagemann, Stefan Clark, Martyn Hall, Alex Rott, Helmut Brutel-Vuilmet, Claire Kim, Hyungjun Menard, Cecile B. Mudryk, Lawrence Thackeray, Chad Wang, Libo Arduini, Gabriele Balsamo, Gianpaolo Bartlett, Paul Boike, Julia Boone, Aaron Cheruy, Frederique Colin, Jeanne Cuntz, Matthias Dai, Yongjiu Decharme, Bertrand Derry, Jeff Ducharne, Agnes Dutra, Emanuel Fang, Xing Fierz, Charles Ghattas, Josephine Gusev, Yeugeniy Haverd, Vanessa Kontu, Anna Lafaysse, Matthieu Law, Rachel Lawrence, Dave Li, Weiping Marke, Thomas Marks, Danny Menegoz, Martin Nasonova, Olga Nitta, Tomoko Niwano, Masashi Pomeroy, John Raleigh, Mark S. Schaedler, Gerd Semenov, Vladimir Smirnova, Tanya G. Stacke, Tobias Strasser, Ulrich Svenson, Sean Turkov, Dmitry Wang, Tao Wever, Nander Yuan, Hua Zhou, Wenyan Zhu, Dan Menard, Cecile/F-7860-2014; Raleigh, Mark S/M-7687-2015; Krinner, Gerhard/A-6450-2011; Balsamo, Gianpaolo/M-5734-2019; Flanner, Mark/C-6139-2011; Nasonova, Olga/B-6093-2014; KIM, HYUNGJUN/I-5099-2014; Dutra, Emanuel/A-3774-2010; Turkov, Dmitry/Y-3186-2018; gusev, yeugeniy/G-4711-2014; Kontu, Anna/O-8886-2014; Zhu, Dan/J-4450-2019; Balsamo, Gianpaolo/I-3362-2013; Niwano, Masashi/N-6723-2016 Menard, Cecile/0000-0003-2166-9523; Raleigh, Mark S/0000-0002-1303-3472; Krinner, Gerhard/0000-0002-2959-5920; Balsamo, Gianpaolo/0000-0002-1745-3634; Flanner, Mark/0000-0003-4012-174X; KIM, HYUNGJUN/0000-0003-1083-8416; Dutra, Emanuel/0000-0002-0643-2643; Turkov, Dmitry/0000-0002-1813-757X; gusev, yeugeniy/0000-0003-3886-2143; Kontu, Anna/0000-0001-6880-6260; Zhu, Dan/0000-0002-5857-1899; Balsamo, Gianpaolo/0000-0002-1745-3634; Fang, Xing/0000-0002-4333-4815; Decharme, Bertrand/0000-0002-8661-1464; Niwano, Masashi/0000-0003-3121-3802 1991-9603; International audience; This paper describes ESM-SnowMIP, an international coordinated modelling effort to evaluate current snow schemes, including snow schemes that are included in Earth system models, in a wide variety of settings against local and global observations. The project aims to identify crucial processes and characteristics that need to be improved in snow models in the context of local-and global-scale modelling. A further objective of ESM-SnowMIP is to better quantify snow-related feedbacks in the Earth system. Although it is not part of the sixth phase of the Coupled Model Intercom-parison Project (CMIP6), ESM-SnowMIP is tightly linked to the CMIP6-endorsed Land Surface, Snow and Soil Moisture Model Intercomparison (LS3MIP).

Published
2018

28. ESM-SnowMIP: Assessing models and quantifying snow-related climate feedbacks

Author

Krinner, Gerhard, primary, Derksen, Chris, additional, Essery, Richard, additional, Flanner, Mark, additional, Hagemann, Stefan, additional, Clark, Martyn, additional, Hall, Alex, additional, Rott, Helmut, additional, Brutel-Vuilmet, Claire, additional, Kim, Hyungjun, additional, Ménard, Cécile B., additional, Mudryk, Lawrence, additional, Thackeray, Chad, additional, Wang, Libo, additional, Arduini, Gabriele, additional, Balsamo, Gianpaolo, additional, Bartlett, Paul, additional, Boike, Julia, additional, Boone, Aaron, additional, Chéruy, Frédérique, additional, Colin, Jeanne, additional, Cuntz, Matthias, additional, Dai, Yongjiu, additional, Decharme, Bertrand, additional, Derry, Jeff, additional, Ducharne, Agnès, additional, Dutra, Emanuel, additional, Fang, Xing, additional, Fierz, Charles, additional, Ghattas, Josephine, additional, Gusev, Yeugeniy, additional, Haverd, Vanessa, additional, Kontu, Anna, additional, Lafaysse, Matthieu, additional, Law, Rachel, additional, Lawrence, Dave, additional, Li, Weiping, additional, Marke, Thomas, additional, Marks, Danny, additional, Nasonova, Olga, additional, Nitta, Tomoko, additional, Niwano, Masahi, additional, Pomeroy, John, additional, Raleigh, Mark S., additional, Schaedler, Gerd, additional, Semenov, Vladimir, additional, Smirnova, Tanya, additional, Stacke, Tobias, additional, Strasser, Ulrich, additional, Svenson, Sean, additional, Turkov, Dmitry, additional, Wang, Tao, additional, Wever, Nander, additional, Yuan, Hua, additional, and Zhou, Wenyan, additional

Published
2018
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30. Canadian snow and sea ice: assessment of snow, sea ice, and related climate processes in Canada's Earth system model and climate-prediction system

Author

Kushner, Paul J., primary, Mudryk, Lawrence R., additional, Merryfield, William, additional, Ambadan, Jaison T., additional, Berg, Aaron, additional, Bichet, Adéline, additional, Brown, Ross, additional, Derksen, Chris, additional, Déry, Stephen J., additional, Dirkson, Arlan, additional, Flato, Greg, additional, Fletcher, Christopher G., additional, Fyfe, John C., additional, Gillett, Nathan, additional, Haas, Christian, additional, Howell, Stephen, additional, Laliberté, Frédéric, additional, McCusker, Kelly, additional, Sigmond, Michael, additional, Sospedra-Alfonso, Reinel, additional, Tandon, Neil F., additional, Thackeray, Chad, additional, Tremblay, Bruno, additional, and Zwiers, Francis W., additional

Published
2018
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31. Canadian snow and sea ice: historical trends and projections

Author

Mudryk, Lawrence R., primary, Derksen, Chris, additional, Howell, Stephen, additional, Laliberté, Fred, additional, Thackeray, Chad, additional, Sospedra-Alfonso, Reinel, additional, Vionnet, Vincent, additional, Kushner, Paul J., additional, and Brown, Ross, additional

Published
2018
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33. Assessment of Snow, Sea Ice, and Related Climate Processes in Canada's Earth-System Model and Climate Prediction System

Author

Kushner, Paul J., primary, Mudryk, Lawrence R., additional, Merryfield, William, additional, Ambadan, Jaison T., additional, Berg, Aaron, additional, Bichet, Adéline, additional, Brown, Ross, additional, Derksen, Christopher P., additional, Déry, Stephen J., additional, Dirkson, Arlan, additional, Flato, Greg, additional, Fletcher, Christopher G., additional, Fyfe, John C., additional, Gillett, Nathan, additional, Haas, Christian, additional, Howell, Stephen, additional, Laliberté, Frédéric, additional, McCusker, Kelly, additional, Sigmond, Michael, additional, Sospreda-Alfonso, Reinel, additional, Tandon, Neil F., additional, Thackeray, Chad, additional, Tremblay, Bruno, additional, and Zwiers, Francis W., additional

Published
2017
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34. Snow albedo feedback: Current knowledge, importance, outstanding issues and future directions

Author

Thackeray, Chad W., Fletcher, Christopher G., Thackeray, Chad W., and Fletcher, Christopher G.

Abstract

Over the past decade, substantial progress has been made in improving our understanding of surface albedo feedbacks, where changes in surface albedo from warming (cooling) can cause increases (decreases) in absorbed solar radiation, amplifying the initial warming (cooling). The goal of this review is to synthesize and assess recent research into the feedback caused by changing continental snow cover, or snow albedo feedback (SAF). Four main topics are evaluated: (i) the importance of SAF to the global energy budget, (ii) estimates of SAF from various data sources, (iii) factors influencing the spread in SAF, and (iv) outstanding issues related to our understanding of the physical processes that control SAF (and their uncertainties). SAF is found to exert a small influence on a global scale, with amplitude of ∼ 0.1 Wm−2 K−1, roughly 7% of the strength of water vapor feedback. However, SAF is an important driver of regional climate change over Northern Hemisphere (NH) extratropical land, where observation-based estimates show a peak feedback of around 1% decrease in surface albedo per degree of warming during spring. Viewed collectively, the current generation of climate models represent this process accurately, but several models still use outdated parameterizations of snow and surface albedo that contribute to biases that impact the simulation of SAF. This discussion serves to synthesize and evaluate previously published literature, while highlighting promising directions being taken at the forefront of research such as high resolution modeling and the use of large ensembles.

Published
2016
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36. ESM-SnowMIP: Assessing models and quantifying snow-related climate feedbacks.

Author

Krinner, Gerhard, Derksen, Chris, Essery, Richard, Flanner, Mark, Hagemann, Stefan, Clark, Martyn, Hall, Alex, Rott, Helmut, Brutel-Vuilmet, Claire, Hyungjun Kim, Ménard, Cécile B., Mudryk, Lawrence, Thackeray, Chad, Libo Wang, Arduini, Gabriele, Balsamo, Gianpaolo, Bartlett, Paul, Boike, Julia, Boone, Aaron, and Chéruy, Frédérique

Subjects
EARTH system science, SNOW, SOIL moisture
Abstract

This paper describes ESM-SnowMIP, an international coordinated modelling effort to evaluate current snow schemes against local and global observations in a wide variety of settings, including snow schemes that are included in Earth System Models. The project aims at identifying crucial processes and snow characteristics that need to be improved in snow models in the context of local- and global-scale modeling. A further objective of ESM-SnowMIP is to better quantify snow-related feedbacks in the Earth system. ESM-SnowMIP is tightly linked to the Land Surface, Snow and Soil Moisture Model Intercomparison Project, which in turn is part of the 6th phase of the Coupled Model Intercomparison Project (CMIP6). [ABSTRACT FROM AUTHOR]

Published
2018
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40. ESM-SnowMIP: assessing snow models and quantifying snow-related climate feedbacks

Author

Krinner, Gerhard, Derksen, Chris, Essery, Richard, Flanner, Mark, Hagemann, Stefan, Clark, Martyn, Hall, Alex, Rott, Helmut, Brutel-Vuilmet, Claire, Kim, Hyungjun, Ménard, Cécile B., Mudryk, Lawrence, Thackeray, Chad, Wang, Libo, Arduini, Gabriele, Balsamo, Gianpaolo, Bartlett, Paul, Boike, Julia, Boone, Aaron, Chéruy, Frédérique, Colin, Jeanne, Cuntz, Matthias, Dai, Yongjiu, Decharme, Bertrand, Derry, Jeff, Ducharne, Agnès, Dutra, Emanuel, Fang, Xing, Fierz, Charles, Ghattas, Josephine, Gusev, Yeugeniy, Haverd, Vanessa, Kontu, Anna, Lafaysse, Matthieu, Law, Rachel, Lawrence, Dave, Li, Weiping, Marke, Thomas, Marks, Danny, Ménégoz, Martin, Nasonova, Olga, Nitta, Tomoko, Niwano, Masashi, Pomeroy, John, Raleigh, Mark S., Schaedler, Gerd, Semenov, Vladimir, Smirnova, Tanya G., Stacke, Tobias, Strasser, Ulrich, Svenson, Sean, Turkov, Dmitry, Wang, Tao, Wever, Nander, Yuan, Hua, Zhou, Wenyan, and Zhu, Dan

Subjects
13. Climate action

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