Deriving brown carbon from multiwavelength absorption measurements: method and application to AERONET and Aethalometer observations

Xuan Wang; Colette L. Heald; Arthur J. Sedlacek; Suzane S. de Sá; Scot T. Martin; M. Lizabeth Alexander; Thomas B. Watson; Allison C. Aiken; Stephen R. Springston; Paulo Artaxo

doi:10.5194/acp-16-12733-2016

Deriving brown carbon from multiwavelength absorption measurements: method and application to AERONET and Aethalometer observations

Xuan Wang^*, Colette L. Heald, Arthur J. Sedlacek, Suzane S. de Sá, Scot T. Martin, M. Lizabeth Alexander, Thomas B. Watson, Allison C. Aiken, Stephen R. Springston, Paulo Artaxo

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

150 Citations (Scopus)

29 Downloads (CityUHK Scholars)

Abstract

The radiative impact of organic aerosols (OA) is a large source of uncertainty in estimating the global direct radiative effect (DRE) of aerosols. This radiative impact includes not only light scattering but also light absorption from a subclass of OA referred to as brown carbon (BrC). However, the absorption properties of BrC are poorly understood, leading to large uncertainties in modeling studies. To obtain observational constraints from measurements, a simple absorption Ångström exponent (AAE) method is often used to separate the contribution of BrC absorption from that of black carbon (BC). However, this attribution method is based on assumptions regarding the spectral dependence of BC that are often violated in the ambient atmosphere. Here we develop a new AAE method which improves upon previous approaches by using the information from the wavelength-dependent measurements themselves and by allowing for an atmospherically relevant range of BC properties, rather than fixing these at a single assumed value. We note that constraints on BC optical properties and mixing state would help further improve this method. We apply this method to multiwavelength absorption aerosol optical depth (AAOD) measurements at AERONET sites worldwide and surface aerosol absorption measurements at multiple ambient sites. We estimate that BrC globally contributes up to 40 % of the seasonally averaged absorption at 440 nm. We find that the mass absorption coefficient of OA (OA-MAC) is positively correlated with the BC ∕ OA mass ratio. Based on the variability in BC properties and BC ∕ OA emission ratio, we estimate a range of 0.05–1.5 m² g⁻¹ for OA-MAC at 440 nm. Using the combination of AERONET and OMI UV absorption observations we estimate that the AAE₃₈₈∕_440 nm for BrC is generally ∼ 4 worldwide, with a smaller value in Europe (< 2). Our analyses of observations at two surface sites (Cape Cod, to the southeast of Boston, and the GoAmazon2014/5 T3 site, to the west of Manaus, Brazil) reveal no significant relationship between BrC absorptivity and photochemical aging in urban-influenced conditions. However, the absorption of BrC measured during the biomass burning season near Manaus is found to decrease with photochemical aging with a lifetime of ∼ 1 day. This lifetime is comparable to previous observations within a biomass burning plume but much slower than estimated from laboratory studies. Given the large uncertainties associated with AERONET retrievals of AAOD, the most challenging aspect of our analysis is that an accurate, globally distributed, multiple-wavelength aerosol absorption measurement dataset is unavailable at present. Thus, achieving a better understanding of the properties, evolution, and impacts of global BrC will rely on the future deployment of accurate multiple-wavelength absorption measurements to which AAE methods, such as the approach developed here, can be applied.

Original language	English
Pages (from-to)	12733-12752
Number of pages	20
Journal	Atmospheric Chemistry and Physics
Volume	16
Issue number	19
Online published	13 Oct 2016
DOIs	https://doi.org/10.5194/acp-16-12733-2016
Publication status	Published - 2016
Externally published	Yes

Funding

This work was supported by the EPA-STAR program. Although the research described in this article was funded in part by the US EPA through grant/cooperative agreement RD-83503301, it has not been subjected to the EPA's required peer and policy review and therefore does not necessarily reflect the views of the EPA and no official endorsement should be inferred. The GoAmazon2014/5 and TCAP data were obtained from the Atmospheric Radiation Measurement (ARM) Climate Research Facility, a US Department of Energy Office of Science user facility sponsored by the Office of Biological and Environmental Research. For the GoAmazon2014/5 data, we also acknowledge the support from the Central Office of the Large Scale Biosphere Atmosphere Experiment in Amazonia (LBA), the Instituto Nacional de Pesquisas da Amazonia (INPA), and the Universidade do Estado do Amazonia (UEA). The work of GoAmazon2014/5 campaign was conducted under 001030/2012-4 of the Brazilian National Council for Scientific and Technological Development (CNPq). The AMS measurement at GoAmazon2014/5-T3 site was performed using EMSL, a DOE Office of Science User Facility sponsored by the Office of Biological and Environmental Research and located at Pacific Northwest National Laboratory. We thank Jesse Kroll, Eleanor Browne, Kelsey Boulanger, Anthony Carasquillo, and Kelly Daumit for AMS measurement during TCAP. We also thank the Norwegian Institute for Air Research (NILU) and the NOAA Earth System Research Laboratory for providing the EMEP and NOAA/ESRL background site measurements, as well as the AERONET staff for establishing and maintaining the sun photometer network used in this study.

Research Keywords

AEROSOL LIGHT-ABSORPTION
FOSSIL-FUEL COMBUSTION
BLACK CARBON
OPTICAL-PROPERTIES
ORGANIC AEROSOL
CROSS-SECTION
SPECTRAL DEPENDENCE
ANGSTROM EXPONENT
MIXING STATE
BIOMASS

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This full text is made available under CC-BY 3.0. https://creativecommons.org/licenses/by/3.0/

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Wang, X., Heald, C. L., Sedlacek, A. J., de Sá, S. S., Martin, S. T., Alexander, M. L., Watson, T. B., Aiken, A. C., Springston, S. R., & Artaxo, P. (2016). Deriving brown carbon from multiwavelength absorption measurements: method and application to AERONET and Aethalometer observations. Atmospheric Chemistry and Physics, 16(19), 12733-12752. https://doi.org/10.5194/acp-16-12733-2016

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title = "Deriving brown carbon from multiwavelength absorption measurements: method and application to AERONET and Aethalometer observations",

abstract = "The radiative impact of organic aerosols (OA) is a large source of uncertainty in estimating the global direct radiative effect (DRE) of aerosols. This radiative impact includes not only light scattering but also light absorption from a subclass of OA referred to as brown carbon (BrC). However, the absorption properties of BrC are poorly understood, leading to large uncertainties in modeling studies. To obtain observational constraints from measurements, a simple absorption {\AA}ngstr{\"o}m exponent (AAE) method is often used to separate the contribution of BrC absorption from that of black carbon (BC). However, this attribution method is based on assumptions regarding the spectral dependence of BC that are often violated in the ambient atmosphere. Here we develop a new AAE method which improves upon previous approaches by using the information from the wavelength-dependent measurements themselves and by allowing for an atmospherically relevant range of BC properties, rather than fixing these at a single assumed value. We note that constraints on BC optical properties and mixing state would help further improve this method. We apply this method to multiwavelength absorption aerosol optical depth (AAOD) measurements at AERONET sites worldwide and surface aerosol absorption measurements at multiple ambient sites. We estimate that BrC globally contributes up to 40 % of the seasonally averaged absorption at 440 nm. We find that the mass absorption coefficient of OA (OA-MAC) is positively correlated with the BC ∕ OA mass ratio. Based on the variability in BC properties and BC ∕ OA emission ratio, we estimate a range of 0.05–1.5 m2 g−1 for OA-MAC at 440 nm. Using the combination of AERONET and OMI UV absorption observations we estimate that the AAE388∕440 nm for BrC is generally ∼ 4 worldwide, with a smaller value in Europe (< 2). Our analyses of observations at two surface sites (Cape Cod, to the southeast of Boston, and the GoAmazon2014/5 T3 site, to the west of Manaus, Brazil) reveal no significant relationship between BrC absorptivity and photochemical aging in urban-influenced conditions. However, the absorption of BrC measured during the biomass burning season near Manaus is found to decrease with photochemical aging with a lifetime of ∼ 1 day. This lifetime is comparable to previous observations within a biomass burning plume but much slower than estimated from laboratory studies. Given the large uncertainties associated with AERONET retrievals of AAOD, the most challenging aspect of our analysis is that an accurate, globally distributed, multiple-wavelength aerosol absorption measurement dataset is unavailable at present. Thus, achieving a better understanding of the properties, evolution, and impacts of global BrC will rely on the future deployment of accurate multiple-wavelength absorption measurements to which AAE methods, such as the approach developed here, can be applied. ",

keywords = "AEROSOL LIGHT-ABSORPTION, FOSSIL-FUEL COMBUSTION, BLACK CARBON, OPTICAL-PROPERTIES, ORGANIC AEROSOL, CROSS-SECTION, SPECTRAL DEPENDENCE, ANGSTROM EXPONENT, MIXING STATE, BIOMASS",

author = "Xuan Wang and Heald, {Colette L.} and Sedlacek, {Arthur J.} and {de S{\'a}}, {Suzane S.} and Martin, {Scot T.} and Alexander, {M. Lizabeth} and Watson, {Thomas B.} and Aiken, {Allison C.} and Springston, {Stephen R.} and Paulo Artaxo",

year = "2016",

doi = "10.5194/acp-16-12733-2016",

language = "English",

volume = "16",

pages = "12733--12752",

journal = "Atmospheric Chemistry and Physics",

issn = "1680-7316",

publisher = "Copernicus Publications",

number = "19",

}

Wang, X, Heald, CL, Sedlacek, AJ, de Sá, SS, Martin, ST, Alexander, ML, Watson, TB, Aiken, AC, Springston, SR & Artaxo, P 2016, 'Deriving brown carbon from multiwavelength absorption measurements: method and application to AERONET and Aethalometer observations', Atmospheric Chemistry and Physics, vol. 16, no. 19, pp. 12733-12752. https://doi.org/10.5194/acp-16-12733-2016

Deriving brown carbon from multiwavelength absorption measurements: method and application to AERONET and Aethalometer observations. / Wang, Xuan; Heald, Colette L.; Sedlacek, Arthur J. et al.
In: Atmospheric Chemistry and Physics, Vol. 16, No. 19, 2016, p. 12733-12752.

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

TY - JOUR

T1 - Deriving brown carbon from multiwavelength absorption measurements

T2 - method and application to AERONET and Aethalometer observations

AU - Wang, Xuan

AU - Heald, Colette L.

AU - Sedlacek, Arthur J.

AU - de Sá, Suzane S.

AU - Martin, Scot T.

AU - Alexander, M. Lizabeth

AU - Watson, Thomas B.

AU - Aiken, Allison C.

AU - Springston, Stephen R.

AU - Artaxo, Paulo

PY - 2016

Y1 - 2016

N2 - The radiative impact of organic aerosols (OA) is a large source of uncertainty in estimating the global direct radiative effect (DRE) of aerosols. This radiative impact includes not only light scattering but also light absorption from a subclass of OA referred to as brown carbon (BrC). However, the absorption properties of BrC are poorly understood, leading to large uncertainties in modeling studies. To obtain observational constraints from measurements, a simple absorption Ångström exponent (AAE) method is often used to separate the contribution of BrC absorption from that of black carbon (BC). However, this attribution method is based on assumptions regarding the spectral dependence of BC that are often violated in the ambient atmosphere. Here we develop a new AAE method which improves upon previous approaches by using the information from the wavelength-dependent measurements themselves and by allowing for an atmospherically relevant range of BC properties, rather than fixing these at a single assumed value. We note that constraints on BC optical properties and mixing state would help further improve this method. We apply this method to multiwavelength absorption aerosol optical depth (AAOD) measurements at AERONET sites worldwide and surface aerosol absorption measurements at multiple ambient sites. We estimate that BrC globally contributes up to 40 % of the seasonally averaged absorption at 440 nm. We find that the mass absorption coefficient of OA (OA-MAC) is positively correlated with the BC ∕ OA mass ratio. Based on the variability in BC properties and BC ∕ OA emission ratio, we estimate a range of 0.05–1.5 m2 g−1 for OA-MAC at 440 nm. Using the combination of AERONET and OMI UV absorption observations we estimate that the AAE388∕440 nm for BrC is generally ∼ 4 worldwide, with a smaller value in Europe (< 2). Our analyses of observations at two surface sites (Cape Cod, to the southeast of Boston, and the GoAmazon2014/5 T3 site, to the west of Manaus, Brazil) reveal no significant relationship between BrC absorptivity and photochemical aging in urban-influenced conditions. However, the absorption of BrC measured during the biomass burning season near Manaus is found to decrease with photochemical aging with a lifetime of ∼ 1 day. This lifetime is comparable to previous observations within a biomass burning plume but much slower than estimated from laboratory studies. Given the large uncertainties associated with AERONET retrievals of AAOD, the most challenging aspect of our analysis is that an accurate, globally distributed, multiple-wavelength aerosol absorption measurement dataset is unavailable at present. Thus, achieving a better understanding of the properties, evolution, and impacts of global BrC will rely on the future deployment of accurate multiple-wavelength absorption measurements to which AAE methods, such as the approach developed here, can be applied.

AB - The radiative impact of organic aerosols (OA) is a large source of uncertainty in estimating the global direct radiative effect (DRE) of aerosols. This radiative impact includes not only light scattering but also light absorption from a subclass of OA referred to as brown carbon (BrC). However, the absorption properties of BrC are poorly understood, leading to large uncertainties in modeling studies. To obtain observational constraints from measurements, a simple absorption Ångström exponent (AAE) method is often used to separate the contribution of BrC absorption from that of black carbon (BC). However, this attribution method is based on assumptions regarding the spectral dependence of BC that are often violated in the ambient atmosphere. Here we develop a new AAE method which improves upon previous approaches by using the information from the wavelength-dependent measurements themselves and by allowing for an atmospherically relevant range of BC properties, rather than fixing these at a single assumed value. We note that constraints on BC optical properties and mixing state would help further improve this method. We apply this method to multiwavelength absorption aerosol optical depth (AAOD) measurements at AERONET sites worldwide and surface aerosol absorption measurements at multiple ambient sites. We estimate that BrC globally contributes up to 40 % of the seasonally averaged absorption at 440 nm. We find that the mass absorption coefficient of OA (OA-MAC) is positively correlated with the BC ∕ OA mass ratio. Based on the variability in BC properties and BC ∕ OA emission ratio, we estimate a range of 0.05–1.5 m2 g−1 for OA-MAC at 440 nm. Using the combination of AERONET and OMI UV absorption observations we estimate that the AAE388∕440 nm for BrC is generally ∼ 4 worldwide, with a smaller value in Europe (< 2). Our analyses of observations at two surface sites (Cape Cod, to the southeast of Boston, and the GoAmazon2014/5 T3 site, to the west of Manaus, Brazil) reveal no significant relationship between BrC absorptivity and photochemical aging in urban-influenced conditions. However, the absorption of BrC measured during the biomass burning season near Manaus is found to decrease with photochemical aging with a lifetime of ∼ 1 day. This lifetime is comparable to previous observations within a biomass burning plume but much slower than estimated from laboratory studies. Given the large uncertainties associated with AERONET retrievals of AAOD, the most challenging aspect of our analysis is that an accurate, globally distributed, multiple-wavelength aerosol absorption measurement dataset is unavailable at present. Thus, achieving a better understanding of the properties, evolution, and impacts of global BrC will rely on the future deployment of accurate multiple-wavelength absorption measurements to which AAE methods, such as the approach developed here, can be applied.

KW - AEROSOL LIGHT-ABSORPTION

KW - FOSSIL-FUEL COMBUSTION

KW - BLACK CARBON

KW - OPTICAL-PROPERTIES

KW - ORGANIC AEROSOL

KW - CROSS-SECTION

KW - SPECTRAL DEPENDENCE

KW - ANGSTROM EXPONENT

KW - MIXING STATE

KW - BIOMASS

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DO - 10.5194/acp-16-12733-2016

M3 - RGC 21 - Publication in refereed journal

SN - 1680-7316

VL - 16

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EP - 12752

JO - Atmospheric Chemistry and Physics

JF - Atmospheric Chemistry and Physics

IS - 19

ER -

Deriving brown carbon from multiwavelength absorption measurements: method and application to AERONET and Aethalometer observations

Abstract

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Research Keywords

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