Climate response of direct radiative forcing of anthropogenic black carbon

Chung, S. H.; Seinfeld, John H.

doi:10.1029/2004jd005441

Cited by 274 publications

(239 citation statements)

References 51 publications

(161 reference statements)

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“…However, the largest temperature response in all simulations is simulated in the Northern Hemisphere high latitudes. This agrees with previous GCM studies, which show that temperature response to RF is highest in the high latitude regions due to associated ice albedo feedbacks (Chung and Seinfeld 2005;Joshi et al 2003;Boer and Yu 2003;Forster et al 2000). Except for the high latitude regions, the temperature response due to aerosol forcing resembles to a large part the warming pattern caused by increasing GHG in the Northern Hemisphere (c.f.…”

Section: Temperature Response and Climate Sensitivitysupporting

confidence: 82%

A GCM study of future climate response to aerosol pollution reductions

et al. 2009

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We use the global atmospheric GCM aerosol model ECHAM5-HAM to asses possible impacts of future air pollution mitigation strategies on climate. Air quality control strategies focus on the reduction of aerosol emissions. Here we investigate the extreme case of a maximum feasible end-of-pipe abatement of aerosols in the near term future (2030) in combination with increasing greenhouse gas (GHG) concentrations. The temperature response of increasing GHG concentrations and reduced aerosol emissions leads to a global annual mean equilibrium temperature response of 2.18 K. When aerosols are maximally abated only in the Industry and Powerplant sector, while other sectors stay with currently enforced regulations, the temperature response is 1.89 K. A maximum feasible abatement applied in the Domestic and Transport sector, while other sectors remain with the current legislation, leads to a temperature response of 1.39 K. Increasing GHG concentrations alone lead to a temperature response of 1.20 K. We also simulate 2-5% increases in global mean precipitation among all scenarios considered, and the hydrological sensitivity is found to be significantly higher for aerosols than for GHGs. Our study, thus highlights the huge potential impact of future air pollution mitigation strategies on climate and supports the need for urgent GHG emission reductions. GHG and aerosol forcings are not independent as both affect and are influenced by changes in the hydrological cycle. However, within the given range of changes in aerosol emissions and GHG concentrations considered in this study, the climate response towards increasing GHG concentrations and decreasing aerosols emissions is additive.

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Section: Temperature Response and Climate Sensitivitysupporting

confidence: 82%

A GCM study of future climate response to aerosol pollution reductions

et al. 2009

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“…Some model calculations suggest that its climate forcing may rival that of methane, and that the present-day global warming due to black carbon may be as much as 0.3-0.4 • C (Jacobson, 2004;Chung and Seinfeld, 2005), while others estimate a smaller climate effect from this substance (Jones et al, 2005). Consequently, there is substantial controversy about the benefits of reducing "BC" as a strategy to mitigate global warming (Hansen et al, 2000;Jacobson, 2002;Bond and Sun, 2005).…”

Section: Introductionmentioning

confidence: 99%

Black carbon or brown carbon? The nature of light-absorbing carbonaceous aerosols

Andreae

Gelencsér²

2006

Atmos. Chem. Phys.

1,726

1,033

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Abstract. Although the definition and measurement techniques for atmospheric "black carbon" ("BC") or "elemental carbon'' ("EC") have long been subjects of scientific controversy, the recent discovery of light-absorbing carbon that is not black ("brown carbon, Cbrown") makes it imperative to reassess and redefine the components that make up light-absorbing carbonaceous matter (LAC) in the atmosphere. Evidence for the atmospheric presence of Cbrown comes from (1) spectral aerosol light absorption measurements near specific combustion sources, (2) observations of spectral properties of water extracts of continental aerosol, (3) laboratory studies indicating the formation of light-absorbing organic matter in the atmosphere, and (4) indirectly from the chemical analogy of aerosol species to colored natural humic substances. We show that brown carbon may severely bias measurements of "BC" and "EC" over vast parts of the troposphere, especially those strongly polluted by biomass burning, where the mass concentration of Cbrown is high relative to that of soot carbon. Chemical measurements to determine "EC" are biased by the refractory nature of Cbrown as well as by complex matrix interferences. Optical measurements of "BC" suffer from a number of problems: (1) many of the presently used instruments introduce a substantial bias into the determination of aerosol light absorption, (2) there is no unique conversion factor between light absorption and "EC" or "BC" concentration in ambient aerosols, and (3) the difference in spectral properties between the different types of LAC, as well as the chemical complexity of Cbrown, lead to several conceptual as well as practical complications. We also suggest that due to the sharply increasing absorption of Cbrown towards the UV, single-wavelength light absorption measurements may not be adequate for the assessment of absorption of solar radiation in the troposphere. We discuss the possible consequences of these effects for our understanding of tropospheric processes, including their influence on UV-irradiance, atmospheric photochemistry and radiative transfer in clouds.

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“…Elemental carbon (EC, equivalent to black carbon) is thought to dominate light absorption by aerosols and is most efficient at absorbing visible light (Bond et al, 2004), with a climate forcing value of þ1.1 W m À2 , with 90% uncertainty bounds of þ0.17 to þ2.1 W m À2 , resulting in a net global warming of up to 0.8 C Chung and Seinfeld, 2005;Ramanathan and Carmichael, 2008;Bond et al, 2013). Among atmospheric pollutants it is second only to CO 2 in potential forcing (Bond et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Urban impacts on regional carbonaceous aerosols: Case study in central Texas

Barrett

Sheesley

2014

Journal of the Air & Waste Management Association

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Rural and background sites provide valuable information on the concentration and optical properties of organic, elemental, and water-soluble organic carbon (OC, EC, and WSOC), which are relevant for understanding the climate forcing potential of regional atmospheric aerosols. Implications: Background concentration and absorption measurements are essential in determining regional potential radiative forcing due to atmospheric aerosols. Back trajectory, chemical, and optical analysis of PM 2.5 was used to determine climatic and air quality implications of urban outflow to a regional receptor site, representative of the central United States. Results indicate that central Texas organic carbon has mixed urban and rural sources, while elemental carbon is controlled by the transport of urban emissions. Analysis of aerosol absorption showed black carbon as the dominant absorber, with less brown carbon absorption than regional studies in California and the southeastern United States.

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Climate response of direct radiative forcing of anthropogenic black carbon

Cited by 274 publications

References 51 publications

A GCM study of future climate response to aerosol pollution reductions

A GCM study of future climate response to aerosol pollution reductions

Black carbon or brown carbon? The nature of light-absorbing carbonaceous aerosols

Urban impacts on regional carbonaceous aerosols: Case study in central Texas

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