Rapid Adjustments Cause Weak Surface Temperature Response to Increased Black Carbon Concentrations

Camilla Weum Stjern; Bjørn Hallvard Samset; Gunnar Myhre; Piers M. Forster; Øivind Hodnebrog; Timothy Andrews; Olivier Boucher; Gregory Faluvegi; Trond Iversen; Matthew Kasoar; Viatcheslav Kharin; Alf Kirkevåg; Jean François Lamarque; Dirk Olivié; Thomas Richardson; Dilshad Shawki; Drew Shindell; Christopher J. Smith; Toshihiko Takemura; Apostolos Voulgarakis

doi:10.1002/2017JD027326

Rapid Adjustments Cause Weak Surface Temperature Response to Increased Black Carbon Concentrations

Camilla Weum Stjern, Bjørn Hallvard Samset, Gunnar Myhre, Piers M. Forster, Øivind Hodnebrog, Timothy Andrews, Olivier Boucher, Gregory Faluvegi, Trond Iversen, Matthew Kasoar, Viatcheslav Kharin, Alf Kirkevåg, Jean François Lamarque, Dirk Olivié, Thomas Richardson, Dilshad Shawki, Drew Shindell, Christopher J. Smith, Toshihiko Takemura, Apostolos Voulgarakis

Center for Oceanic and Atmospheric Research

Research output: Contribution to journal › Article › peer-review

117 Citations (Scopus)

Abstract

We investigate the climate response to increased concentrations of black carbon (BC), as part of the Precipitation Driver Response Model Intercomparison Project (PDRMIP). A tenfold increase in BC is simulated by nine global coupled-climate models, producing a model median effective radiative forcing of 0.82 (ranging from 0.41 to 2.91) W m⁻², and a warming of 0.67 (0.16 to 1.66) K globally and 1.24 (0.26 to 4.31) K in the Arctic. A strong positive instantaneous radiative forcing (median of 2.10 W m⁻² based on five of the models) is countered by negative rapid adjustments (−0.64 W m⁻² for the same five models), which dampen the total surface temperature signal. Unlike other drivers of climate change, the response of temperature and cloud profiles to the BC forcing is dominated by rapid adjustments. Low-level cloud amounts increase for all models, while higher-level clouds are diminished. The rapid temperature response is particularly strong above 400 hPa, where increased atmospheric stabilization and reduced cloud cover contrast the response pattern of the other drivers. In conclusion, we find that this substantial increase in BC concentrations does have considerable impacts on important aspects of the climate system. However, some of these effects tend to offset one another, leaving a relatively small median global warming of 0.47 K per W m⁻²—about 20% lower than the response to a doubling of CO₂. Translating the tenfold increase in BC to the present-day impact of anthropogenic BC (given the emissions used in this work) would leave a warming of merely 0.07 K.

Original language	English
Pages (from-to)	11,462-11,481
Journal	Journal of Geophysical Research: Atmospheres
Volume	122
Issue number	21
DOIs	https://doi.org/10.1002/2017JD027326
Publication status	Published - Nov 16 2017

All Science Journal Classification (ASJC) codes

Atmospheric Science
Geophysics
Earth and Planetary Sciences (miscellaneous)
Space and Planetary Science

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/2017JD027326

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Stjern, C. W., Samset, B. H., Myhre, G., Forster, P. M., Hodnebrog, Ø., Andrews, T., Boucher, O., Faluvegi, G., Iversen, T., Kasoar, M., Kharin, V., Kirkevåg, A., Lamarque, J. F., Olivié, D., Richardson, T., Shawki, D., Shindell, D., Smith, C. J., Takemura, T., & Voulgarakis, A. (2017). Rapid Adjustments Cause Weak Surface Temperature Response to Increased Black Carbon Concentrations. Journal of Geophysical Research: Atmospheres, 122(21), 11,462-11,481. https://doi.org/10.1002/2017JD027326

Stjern, CW, Samset, BH, Myhre, G, Forster, PM, Hodnebrog, Ø, Andrews, T, Boucher, O, Faluvegi, G, Iversen, T, Kasoar, M, Kharin, V, Kirkevåg, A, Lamarque, JF, Olivié, D, Richardson, T, Shawki, D, Shindell, D, Smith, CJ, Takemura, T & Voulgarakis, A 2017, 'Rapid Adjustments Cause Weak Surface Temperature Response to Increased Black Carbon Concentrations', Journal of Geophysical Research: Atmospheres, vol. 122, no. 21, pp. 11,462-11,481. https://doi.org/10.1002/2017JD027326

@article{f2839359894a45519fd65dcab766564c,

title = "Rapid Adjustments Cause Weak Surface Temperature Response to Increased Black Carbon Concentrations",

abstract = "We investigate the climate response to increased concentrations of black carbon (BC), as part of the Precipitation Driver Response Model Intercomparison Project (PDRMIP). A tenfold increase in BC is simulated by nine global coupled-climate models, producing a model median effective radiative forcing of 0.82 (ranging from 0.41 to 2.91) W m−2, and a warming of 0.67 (0.16 to 1.66) K globally and 1.24 (0.26 to 4.31) K in the Arctic. A strong positive instantaneous radiative forcing (median of 2.10 W m−2 based on five of the models) is countered by negative rapid adjustments (−0.64 W m−2 for the same five models), which dampen the total surface temperature signal. Unlike other drivers of climate change, the response of temperature and cloud profiles to the BC forcing is dominated by rapid adjustments. Low-level cloud amounts increase for all models, while higher-level clouds are diminished. The rapid temperature response is particularly strong above 400 hPa, where increased atmospheric stabilization and reduced cloud cover contrast the response pattern of the other drivers. In conclusion, we find that this substantial increase in BC concentrations does have considerable impacts on important aspects of the climate system. However, some of these effects tend to offset one another, leaving a relatively small median global warming of 0.47 K per W m−2—about 20% lower than the response to a doubling of CO2. Translating the tenfold increase in BC to the present-day impact of anthropogenic BC (given the emissions used in this work) would leave a warming of merely 0.07 K.",

author = "Stjern, {Camilla Weum} and Samset, {Bj{\o}rn Hallvard} and Gunnar Myhre and Forster, {Piers M.} and {\O}ivind Hodnebrog and Timothy Andrews and Olivier Boucher and Gregory Faluvegi and Trond Iversen and Matthew Kasoar and Viatcheslav Kharin and Alf Kirkev{\aa}g and Lamarque, {Jean Fran{\c c}ois} and Dirk Olivi{\'e} and Thomas Richardson and Dilshad Shawki and Drew Shindell and Smith, {Christopher J.} and Toshihiko Takemura and Apostolos Voulgarakis",

note = "Funding Information: All model results used for the present study are available to the public through the Norwegian NORSTORE data storage facility. For access, please see instructions at http://www.cicero.uio. no/en/PDRMIP/PDRMIP-data-access. PDRMIP is partly funded through the Norwegian Research Council project NAPEX (project 229778). T. Takemura was supported by the supercomputer system of the National Institute for Environmental Studies, Japan; the Environment Research and Technology Development Fund (S-12-3) of the Ministry of the Environment, Japan; and JSPS KAKENHI grants 15H01728 and 15K12190. D. Olivie, A. Kirkev{\aa}g, and T. Iversen were supported by the Norwegian Research Council through the projects EVA (grant 229771), EarthClim (207711/E10), NOTUR (nn2345k), and NorStore (ns2345k). M. Kasoar and A.Voulgarakis are supported by the Natural Environment Research Council under grant NE/K500872/1. Simulations with HadGEM3-GA4 were performed using the MONSooN system, a collaborative facility supplied under the Joint Weather and Climate Research Programme, which is a strategic partnership between the Met Office and the Natural Environment Research Council. We acknowledge the NASA High-End Computing Program through the NASA Center for Climate Simulation at Goddard Space Flight Center for computational resources to run the GISS-E2R model. Olivier Boucher acknowledges HPC resources from TGCC under the gencmip6 allocation provided by GENCI (Grand Equipement National de Calcul Intensif). T. R. and P. F. were supported by NERC grants NE/K007483/1 and NE/N006038/1. Funding Information: All model results used for the present study are available to the public through the Norwegian NORSTORE data storage facility. For access, please see instructions at http://www.cicero.uio.no/en/PDRMIP/PDRMIP-data-access. PDRMIP is partly funded through the Norwegian Research Council project NAPEX (project 229778). T. Takemura was supported by the supercomputer system of the National Institute for Environmental Studies, Japan; the Environment Research and Technology Development Fund (S-12-3) of the Ministry of the Environment, Japan; and JSPS KAKENHI grants 15H01728 and 15K12190. D. Olivie, A. Kirkev{\aa}g, and T. Iversen were supported by the Norwegian Research Council through the projects EVA (grant 229771), EarthClim (207711/E10), NOTUR (nn2345k), and NorStore (ns2345k). M.Kasoar and A.Voulgarakis are supported by the Natural Environment Research Council under grant NE/K500872/1. Simulations with HadGEM3-GA4 were performed using the MONSooN system, a collaborative facility supplied under the Joint Weather and Climate Research Programme, which is a strategic partnership between the Met Office and the Natural Environment Research Council. We acknowledge the NASA High-End Computing Program through the NASA Center for Climate Simulation at Goddard Space Flight Center for computational resources to run the GISS-E2R model. Olivier Boucher acknowledges HPC resources from TGCC under the gencmip6 allocation provided by GENCI (Grand Equipement National de Calcul Intensif). T. R. and P. F. were supported by NERC grants NE/K007483/1 and NE/N006038/1. Publisher Copyright: {\textcopyright}2017. The Authors.",

year = "2017",

month = nov,

day = "16",

doi = "10.1002/2017JD027326",

language = "English",

volume = "122",

pages = "11,462--11,481",

journal = "Journal of Geophysical Research: Atmospheres",

issn = "2169-897X",

number = "21",

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TY - JOUR

T1 - Rapid Adjustments Cause Weak Surface Temperature Response to Increased Black Carbon Concentrations

AU - Stjern, Camilla Weum

AU - Samset, Bjørn Hallvard

AU - Myhre, Gunnar

AU - Forster, Piers M.

AU - Hodnebrog, Øivind

AU - Andrews, Timothy

AU - Boucher, Olivier

AU - Faluvegi, Gregory

AU - Iversen, Trond

AU - Kasoar, Matthew

AU - Kharin, Viatcheslav

AU - Kirkevåg, Alf

AU - Lamarque, Jean François

AU - Olivié, Dirk

AU - Richardson, Thomas

AU - Shawki, Dilshad

AU - Shindell, Drew

AU - Smith, Christopher J.

AU - Takemura, Toshihiko

AU - Voulgarakis, Apostolos

N1 - Funding Information: All model results used for the present study are available to the public through the Norwegian NORSTORE data storage facility. For access, please see instructions at http://www.cicero.uio. no/en/PDRMIP/PDRMIP-data-access. PDRMIP is partly funded through the Norwegian Research Council project NAPEX (project 229778). T. Takemura was supported by the supercomputer system of the National Institute for Environmental Studies, Japan; the Environment Research and Technology Development Fund (S-12-3) of the Ministry of the Environment, Japan; and JSPS KAKENHI grants 15H01728 and 15K12190. D. Olivie, A. Kirkevåg, and T. Iversen were supported by the Norwegian Research Council through the projects EVA (grant 229771), EarthClim (207711/E10), NOTUR (nn2345k), and NorStore (ns2345k). M. Kasoar and A.Voulgarakis are supported by the Natural Environment Research Council under grant NE/K500872/1. Simulations with HadGEM3-GA4 were performed using the MONSooN system, a collaborative facility supplied under the Joint Weather and Climate Research Programme, which is a strategic partnership between the Met Office and the Natural Environment Research Council. We acknowledge the NASA High-End Computing Program through the NASA Center for Climate Simulation at Goddard Space Flight Center for computational resources to run the GISS-E2R model. Olivier Boucher acknowledges HPC resources from TGCC under the gencmip6 allocation provided by GENCI (Grand Equipement National de Calcul Intensif). T. R. and P. F. were supported by NERC grants NE/K007483/1 and NE/N006038/1. Funding Information: All model results used for the present study are available to the public through the Norwegian NORSTORE data storage facility. For access, please see instructions at http://www.cicero.uio.no/en/PDRMIP/PDRMIP-data-access. PDRMIP is partly funded through the Norwegian Research Council project NAPEX (project 229778). T. Takemura was supported by the supercomputer system of the National Institute for Environmental Studies, Japan; the Environment Research and Technology Development Fund (S-12-3) of the Ministry of the Environment, Japan; and JSPS KAKENHI grants 15H01728 and 15K12190. D. Olivie, A. Kirkevåg, and T. Iversen were supported by the Norwegian Research Council through the projects EVA (grant 229771), EarthClim (207711/E10), NOTUR (nn2345k), and NorStore (ns2345k). M.Kasoar and A.Voulgarakis are supported by the Natural Environment Research Council under grant NE/K500872/1. Simulations with HadGEM3-GA4 were performed using the MONSooN system, a collaborative facility supplied under the Joint Weather and Climate Research Programme, which is a strategic partnership between the Met Office and the Natural Environment Research Council. We acknowledge the NASA High-End Computing Program through the NASA Center for Climate Simulation at Goddard Space Flight Center for computational resources to run the GISS-E2R model. Olivier Boucher acknowledges HPC resources from TGCC under the gencmip6 allocation provided by GENCI (Grand Equipement National de Calcul Intensif). T. R. and P. F. were supported by NERC grants NE/K007483/1 and NE/N006038/1. Publisher Copyright: ©2017. The Authors.

PY - 2017/11/16

Y1 - 2017/11/16

N2 - We investigate the climate response to increased concentrations of black carbon (BC), as part of the Precipitation Driver Response Model Intercomparison Project (PDRMIP). A tenfold increase in BC is simulated by nine global coupled-climate models, producing a model median effective radiative forcing of 0.82 (ranging from 0.41 to 2.91) W m−2, and a warming of 0.67 (0.16 to 1.66) K globally and 1.24 (0.26 to 4.31) K in the Arctic. A strong positive instantaneous radiative forcing (median of 2.10 W m−2 based on five of the models) is countered by negative rapid adjustments (−0.64 W m−2 for the same five models), which dampen the total surface temperature signal. Unlike other drivers of climate change, the response of temperature and cloud profiles to the BC forcing is dominated by rapid adjustments. Low-level cloud amounts increase for all models, while higher-level clouds are diminished. The rapid temperature response is particularly strong above 400 hPa, where increased atmospheric stabilization and reduced cloud cover contrast the response pattern of the other drivers. In conclusion, we find that this substantial increase in BC concentrations does have considerable impacts on important aspects of the climate system. However, some of these effects tend to offset one another, leaving a relatively small median global warming of 0.47 K per W m−2—about 20% lower than the response to a doubling of CO2. Translating the tenfold increase in BC to the present-day impact of anthropogenic BC (given the emissions used in this work) would leave a warming of merely 0.07 K.

AB - We investigate the climate response to increased concentrations of black carbon (BC), as part of the Precipitation Driver Response Model Intercomparison Project (PDRMIP). A tenfold increase in BC is simulated by nine global coupled-climate models, producing a model median effective radiative forcing of 0.82 (ranging from 0.41 to 2.91) W m−2, and a warming of 0.67 (0.16 to 1.66) K globally and 1.24 (0.26 to 4.31) K in the Arctic. A strong positive instantaneous radiative forcing (median of 2.10 W m−2 based on five of the models) is countered by negative rapid adjustments (−0.64 W m−2 for the same five models), which dampen the total surface temperature signal. Unlike other drivers of climate change, the response of temperature and cloud profiles to the BC forcing is dominated by rapid adjustments. Low-level cloud amounts increase for all models, while higher-level clouds are diminished. The rapid temperature response is particularly strong above 400 hPa, where increased atmospheric stabilization and reduced cloud cover contrast the response pattern of the other drivers. In conclusion, we find that this substantial increase in BC concentrations does have considerable impacts on important aspects of the climate system. However, some of these effects tend to offset one another, leaving a relatively small median global warming of 0.47 K per W m−2—about 20% lower than the response to a doubling of CO2. Translating the tenfold increase in BC to the present-day impact of anthropogenic BC (given the emissions used in this work) would leave a warming of merely 0.07 K.

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U2 - 10.1002/2017JD027326

DO - 10.1002/2017JD027326

M3 - Article

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JO - Journal of Geophysical Research: Atmospheres

JF - Journal of Geophysical Research: Atmospheres

IS - 21

ER -

Rapid Adjustments Cause Weak Surface Temperature Response to Increased Black Carbon Concentrations

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