AERONET-based models of smoke-dominated aerosol near source regions and transported over oceans, and implications for satellite retrievals of aerosol optical depth

Sayer, A. M.; Hsu, N. Christina; Eck, T. F.; Smirnov, A.; Holben, B. N.

doi:10.5194/acp-14-11493-2014

Cited by 88 publications

(99 citation statements)

References 122 publications

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“…The AERONET observations of wavelength-dependent absorption are retrieved from the direct and diffuse radiation measured by sun/sky radiometers, but they do not include any aerosol assumptions such as those used in the AERONET retrieval of refractive index and size distribution. AERONET AAOD is widely used to investigate the sources, compositions, and properties of aerosols (Russell et al, 2010;Bond et al, 2014;Sayer et al, 2014). However, we show that the retrieval is an indirect measure of aerosol absorption and that uncertainties and assumptions in the retrieval scheme may impact the reported multiwavelength absorption and introduce subtle inconsistencies with our assumed population of particles.…”

Section: Methods For Deriving Brc Absorption From Observationsmentioning

confidence: 96%

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

et al. 2016

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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 wavelengthdependent 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 m 2 g −1 for OA-MAC at 440 nm. Using the combination of AERONET and OMI UV absorption observations we estimate that the AAE 388/440 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 toPublished by Copernicus Publications on behalf of the European Geosciences Union.

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Section: Methods For Deriving Brc Absorption From Observationsmentioning

confidence: 96%

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

et al. 2016

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“…The VIIRS-retrieved size information, such as AE and fine-mode AOD fraction, can help to constrain the size information, in particular over ocean where size information is more reliable than over land. Meanwhile, the spectral absorption characteristics can be constrained by climatological data derived from AERONET (e.g., Sayer et al, 2014a) or other sources.…”

Section: Discussionmentioning

confidence: 99%

“…In this region, smoke aerosols originate from scattered burning sources as seen by the MODIS fire mask (Giglio et al, 2003), which makes their optical and microphysical properties complicated. Smoke properties can vary according to material burned, combustion type, and aging processes (e.g., Dubovik et al, 2002;Reid et al, 2005;Lee et al, 2010;Sayer et al, 2014a). For the test case, the smoke layer with AOD generally higher than 0.8 (not shown) resides at altitudes ranging from 2-5 km (Fig.…”

Section: Ashe Algorithmmentioning

confidence: 99%

Evaluating the Height of Biomass Burning Smoke Aerosols Retrieved from Synergistic Use of Multiple Satellite Sensors over Southeast Asia

Lee

Hsu

Bettenhausen

et al. 2016

Aerosol Air Qual. Res.

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This study evaluates the height of biomass burning smoke aerosols retrieved from a combined use of Visible Infrared Imaging Radiometer Suite (VIIRS), Ozone Mapping and Profiler Suite (OMPS), and Cloud-Aerosol Lidar with Orthogonal Polarization (CALIOP) observations. The retrieved heights are compared against spaceborne and ground-based lidar measurements during the peak biomass burning season (March and April) over Southeast Asia from 2013 to 2015. Based on the comparison against CALIOP, a quality assurance (QA) procedure is developed. It is found that 74% (81-84%) of the retrieved heights fall within 1 km of CALIOP observations for unfiltered (QA-filtered) data, with root-mean-square error (RMSE) of 1.1 km (0.8-1.0 km). Eliminating the requirement for CALIOP observations from the retrieval process significantly increases the temporal coverage with only a slight decrease in the retrieval accuracy; for best QA data, 64% of data fall within 1 km of CALIOP observations with RMSE of 1.1 km. When compared with Micro-Pulse Lidar Network (MPLNET) measurements deployed at Doi Ang Khang, Thailand, the retrieved heights show RMSE of 1.7 km (1.1 km) for unfiltered (QA-filtered) data for the complete algorithm, and 0.9 km (0.8 km) for the simplified algorithm.

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“…Since biases in FMF are directly related to the biases in AOD at UV wavelengths, a similar tendency to AOD errors is observed (i.e., retrieval bias in the same direction). For AAE, we assume an uncertainty of 0.4, which is an intermediate value between the standard deviation of AAE of smoke aerosols from different source regions [Sayer et al, 2014a] and that of dust [Russell et al, 2010]. The positive (negative) bias in AAE leads to higher (lower) UVAI for a given aerosol loading condition, thereby resulting in negative (positive) bias in ATH.…”

Section: Aerosol Modelmentioning

confidence: 99%

Retrieving the height of smoke and dust aerosols by synergistic use of VIIRS, OMPS, and CALIOP observations

et al. 2015

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This study extends the application of the previously developed Aerosol Single-scattering albedo and layer Height Estimation (ASHE) algorithm, which was originally applied to smoke aerosols only, to both smoke and dust aerosols by including nonspherical dust properties in the retrieval process. The main purpose of the algorithm is to derive aerosol height information over wide areas using aerosol products from multiple satellite sensors simultaneously: aerosol optical depth (AOD) and Ångström exponent from the Visible Infrared Imaging Radiometer Suite (VIIRS), UV aerosol index from the Ozone Mapping and Profiler Suite (OMPS), and total backscatter coefficient profile from the Cloud-Aerosol Lidar with Orthogonal Polarization (CALIOP). The case studies suggest that the ASHE algorithm performs well for both smoke and dust aerosols, showing root-mean-square error of the retrieved aerosol height as compared to CALIOP observations from 0.58 to 1.31 km and mean bias from À0.70 to 1.13 km. In addition, the algorithm shows the ability to retrieve single-scattering albedo to within 0.03 of Aerosol Robotic Network inversion data for moderate to thick aerosol loadings (AOD of~1.0). For typical single-layered aerosol cases, the estimated uncertainty in the retrieved height ranges from 1.20 to 1.80 km over land and from 1.15 to 1.58 km over ocean when favorable conditions are met. Larger errors are observed for multilayered aerosol events, due to the limited sensitivities of the passive sensors to such cases.

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AERONET-based models of smoke-dominated aerosol near source regions and transported over oceans, and implications for satellite retrievals of aerosol optical depth

Cited by 88 publications

References 122 publications

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

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

Evaluating the Height of Biomass Burning Smoke Aerosols Retrieved from Synergistic Use of Multiple Satellite Sensors over Southeast Asia

Retrieving the height of smoke and dust aerosols by synergistic use of VIIRS, OMPS, and CALIOP observations

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