Present-day climate forcing and response from black carbon in snow

We apply our Snow, Ice, and Aerosol Radiative (SNICAR) model, coupled to a general circulation model with prognostic carbon aerosol transport, to improve understanding of climate forcing and response from black carbon (BC) in snow. Building on two previous studies, we account for interannually varyi...

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Published in:Journal of Geophysical Research
Main Authors: Flanner, Mark G, Zender, Charles S, Randerson, James T, Rasch, Philip J
Format: Article in Journal/Newspaper
Language:English
Published: eScholarship, University of California 2007
Subjects:
Physical Sciences and Mathematics
black carbon
snow reflectance
snow albedo feedback
Arctic
albedo
Sea ice
Online Access:http://www.escholarship.org/uc/item/9k7037cz
id ftcdlib:qt9k7037cz
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spelling ftcdlib:qt9k7037cz 2023-05-15T13:11:22+02:00 Present-day climate forcing and response from black carbon in snow Flanner, Mark G Zender, Charles S Randerson, James T Rasch, Philip J 2007-06-05 application/pdf http://www.escholarship.org/uc/item/9k7037cz english eng eScholarship, University of California qt9k7037cz http://www.escholarship.org/uc/item/9k7037cz Attribution (CC BY): http://creativecommons.org/licenses/by/3.0/ CC-BY Flanner, Mark G; Zender, Charles S; Randerson, James T; & Rasch, Philip J. (2007). Present-day climate forcing and response from black carbon in snow. Journal of Geophysical Research, 112(D11). doi:10.1029/2006JD008003. UC Irvine: Department of Earth System Science, UCI. Retrieved from: http://www.escholarship.org/uc/item/9k7037cz Physical Sciences and Mathematics black carbon snow reflectance snow albedo feedback article 2007 ftcdlib https://doi.org/10.1029/2006JD008003 2016-04-02T18:38:06Z We apply our Snow, Ice, and Aerosol Radiative (SNICAR) model, coupled to a general circulation model with prognostic carbon aerosol transport, to improve understanding of climate forcing and response from black carbon (BC) in snow. Building on two previous studies, we account for interannually varying biomass burning BC emissions, snow aging, and aerosol scavenging by snow meltwater. We assess uncertainty in forcing estimates from these factors, as well as BC optical properties and snow cover fraction. BC emissions are the largest source of uncertainty, followed by snow aging. The rate of snow aging determines snowpack effective radius (r e), which directly controls snow reflectance and the magnitude of albedo change caused by BC. For a reasonable r e range, reflectance reduction from BC varies threefold. Inefficient meltwater scavenging keeps hydrophobic impurities near the surface during melt and enhances forcing. Applying biomass burning BC emission inventories for a strong (1998) and weak (2001) boreal fire year, we estimate global annual mean BC/snow surface radiative forcing from all sources (fossil fuel, biofuel, and biomass burning) of +0.054 (0.007–0.13) and +0.049 (0.007–0.12) W m−2, respectively. Snow forcing from only fossil fuel + biofuel sources is +0.043 W m−2 (forcing from only fossil fuels is +0.033 W m−2), suggesting that the anthropogenic contribution to total forcing is at least 80%. The 1998 global land and sea-ice snowpack absorbed 0.60 and 0.23 W m−2, respectively, because of direct BC/snow forcing. The forcing is maximum coincidentally with snowmelt onset, triggering strong snow-albedo feedback in local springtime. Consequently, the “efficacy” of BC/snow forcing is more than three times greater than forcing by CO2. The 1998 and 2001 land snowmelt rates north of 50°N are 28% and 19% greater in the month preceding maximum melt of control simulations without BC in snow. With climate feedbacks, global annual mean 2-meter air temperature warms 0.15 and 0.10°C, when BC is included in snow, whereas annual arctic warming is 1.61 and 0.50°C. Stronger high-latitude climate response in 1998 than 2001 is at least partially caused by boreal fires, which account for nearly all of the 35% biomass burning contribution to 1998 arctic forcing. Efficacy was anomalously large in this experiment, however, and more research is required to elucidate the role of boreal fires, which we suggest have maximum arctic BC/snow forcing potential during April–June. Model BC concentrations in snow agree reasonably well (r = 0.78) with a set of 23 observations from various locations, spanning nearly 4 orders of magnitude. We predict concentrations in excess of 1000 ng g−1 for snow in northeast China, enough to lower snow albedo by more than 0.13. The greatest instantaneous forcing is over the Tibetan Plateau, exceeding 20 W m−2 in some places during spring. These results indicate that snow darkening is an important component of carbon aerosol climate forcing. Article in Journal/Newspaper albedo Arctic black carbon Sea ice University of California: eScholarship Arctic Journal of Geophysical Research 112 D11
institution Open Polar
collection University of California: eScholarship
op_collection_id ftcdlib
language English
topic Physical Sciences and Mathematics
black carbon
snow reflectance
snow albedo feedback
spellingShingle Physical Sciences and Mathematics
black carbon
snow reflectance
snow albedo feedback
Flanner, Mark G
Zender, Charles S
Randerson, James T
Rasch, Philip J
Present-day climate forcing and response from black carbon in snow
topic_facet Physical Sciences and Mathematics
black carbon
snow reflectance
snow albedo feedback
description We apply our Snow, Ice, and Aerosol Radiative (SNICAR) model, coupled to a general circulation model with prognostic carbon aerosol transport, to improve understanding of climate forcing and response from black carbon (BC) in snow. Building on two previous studies, we account for interannually varying biomass burning BC emissions, snow aging, and aerosol scavenging by snow meltwater. We assess uncertainty in forcing estimates from these factors, as well as BC optical properties and snow cover fraction. BC emissions are the largest source of uncertainty, followed by snow aging. The rate of snow aging determines snowpack effective radius (r e), which directly controls snow reflectance and the magnitude of albedo change caused by BC. For a reasonable r e range, reflectance reduction from BC varies threefold. Inefficient meltwater scavenging keeps hydrophobic impurities near the surface during melt and enhances forcing. Applying biomass burning BC emission inventories for a strong (1998) and weak (2001) boreal fire year, we estimate global annual mean BC/snow surface radiative forcing from all sources (fossil fuel, biofuel, and biomass burning) of +0.054 (0.007–0.13) and +0.049 (0.007–0.12) W m−2, respectively. Snow forcing from only fossil fuel + biofuel sources is +0.043 W m−2 (forcing from only fossil fuels is +0.033 W m−2), suggesting that the anthropogenic contribution to total forcing is at least 80%. The 1998 global land and sea-ice snowpack absorbed 0.60 and 0.23 W m−2, respectively, because of direct BC/snow forcing. The forcing is maximum coincidentally with snowmelt onset, triggering strong snow-albedo feedback in local springtime. Consequently, the “efficacy” of BC/snow forcing is more than three times greater than forcing by CO2. The 1998 and 2001 land snowmelt rates north of 50°N are 28% and 19% greater in the month preceding maximum melt of control simulations without BC in snow. With climate feedbacks, global annual mean 2-meter air temperature warms 0.15 and 0.10°C, when BC is included in snow, whereas annual arctic warming is 1.61 and 0.50°C. Stronger high-latitude climate response in 1998 than 2001 is at least partially caused by boreal fires, which account for nearly all of the 35% biomass burning contribution to 1998 arctic forcing. Efficacy was anomalously large in this experiment, however, and more research is required to elucidate the role of boreal fires, which we suggest have maximum arctic BC/snow forcing potential during April–June. Model BC concentrations in snow agree reasonably well (r = 0.78) with a set of 23 observations from various locations, spanning nearly 4 orders of magnitude. We predict concentrations in excess of 1000 ng g−1 for snow in northeast China, enough to lower snow albedo by more than 0.13. The greatest instantaneous forcing is over the Tibetan Plateau, exceeding 20 W m−2 in some places during spring. These results indicate that snow darkening is an important component of carbon aerosol climate forcing.
format Article in Journal/Newspaper
author Flanner, Mark G
Zender, Charles S
Randerson, James T
Rasch, Philip J
author_facet Flanner, Mark G
Zender, Charles S
Randerson, James T
Rasch, Philip J
author_sort Flanner, Mark G
title Present-day climate forcing and response from black carbon in snow
title_short Present-day climate forcing and response from black carbon in snow
title_full Present-day climate forcing and response from black carbon in snow
title_fullStr Present-day climate forcing and response from black carbon in snow
title_full_unstemmed Present-day climate forcing and response from black carbon in snow
title_sort present-day climate forcing and response from black carbon in snow
publisher eScholarship, University of California
publishDate 2007
url http://www.escholarship.org/uc/item/9k7037cz
geographic Arctic
geographic_facet Arctic
genre albedo
Arctic
black carbon
Sea ice
genre_facet albedo
Arctic
black carbon
Sea ice
op_source Flanner, Mark G; Zender, Charles S; Randerson, James T; & Rasch, Philip J. (2007). Present-day climate forcing and response from black carbon in snow. Journal of Geophysical Research, 112(D11). doi:10.1029/2006JD008003. UC Irvine: Department of Earth System Science, UCI. Retrieved from: http://www.escholarship.org/uc/item/9k7037cz
op_relation qt9k7037cz
http://www.escholarship.org/uc/item/9k7037cz
op_rights Attribution (CC BY): http://creativecommons.org/licenses/by/3.0/
op_rightsnorm CC-BY
op_doi https://doi.org/10.1029/2006JD008003
container_title Journal of Geophysical Research
container_volume 112
container_issue D11
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