Optical properties of coated black carbon aggregates: numerical simulations, radiative forcing estimates, and size-resolved parameterization scheme

Optical properties of coated black carbon aggregates: numerical simulations, radiative forcing estimates, and size-resolved parameterization scheme

The formation of black carbon fractal aggregates (BCFAs) from combustion and subsequent ageing involves several stages resulting in modifications of particle size, morphology, and composition over time. To understand and quantify how each of these modifications influences the BC radiative forcing, t...

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Veröffentlicht in:Atmospheric chemistry and physics 2021-09, Vol.21 (17), p.12989-13010
Hauptverfasser: Romshoo, Baseerat, Mueller, Thomas, Pfeifer, Sascha, Saturno, Jorge, Nowak, Andreas, Ciupek, Krzysztof, Quincey, Paul, Wiedensohler, Alfred
Format: Artikel
Sprache:eng
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Absorption
Absorption cross sections
Ageing
Aggregates
Aging
Albedo
Analysis
Asymmetry
Biomass burning
Black carbon
Burning
Carbon
Carbon particles
Coatings
Combustion
Composition
Computer applications
Computing time
Diameters
Dimensions
Environmental Sciences
Environmental Sciences & Ecology
Fractal geometry
Fractals
Laboratories
Life Sciences & Biomedicine
Mathematical models
Meteorology & Atmospheric Sciences
Microscopy
Mobility
Modelling
Morphology
Numerical analysis
Numerical simulations
Optical properties
Parameterization
Parameters
Physical Sciences
Radiative forcing
Scattering
Science & Technology
Visible spectrum
Wavelength
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container_end_page 13010
container_issue 17
container_start_page 12989
container_title Atmospheric chemistry and physics
container_volume 21
creator Romshoo, Baseerat
Mueller, Thomas
Pfeifer, Sascha
Saturno, Jorge
Nowak, Andreas
Ciupek, Krzysztof
Quincey, Paul
Wiedensohler, Alfred
description The formation of black carbon fractal aggregates (BCFAs) from combustion and subsequent ageing involves several stages resulting in modifications of particle size, morphology, and composition over time. To understand and quantify how each of these modifications influences the BC radiative forcing, the optical properties of BCFAs are modelled. Owing to the high computational time involved in numerical modelling, there are some gaps in terms of data coverage and knowledge regarding how optical properties of coated BCFAs vary over the range of different factors (size, shape, and composition). This investigation bridged those gaps by following a state-of-the-art description scheme of BCFAs based on morphology, composition, and wavelength. The BCFA optical properties were investigated as a function of the radius of the primary particle (a(o)), fractal dimension (D-f), fraction of organics (f(organics)), wavelength (lambda), and mobility diameter (D-mob). The optical properties are calculated using the multiple-sphere T-matrix (MSTM) method. For the first time, the modelled optical properties of BC are expressed in terms of mobility diameter (Dmob), making the results more relevant and relatable for ambient and laboratory BC studies. Amongst size, morphology, and composition, all the optical properties showed the highest variability with changing size. The cross sections varied from 0.0001 to 0.1 mu m(2) for BCFA D-mob ranging from 24 to 810 nm. It has been shown that MACBC and single-scattering albedo (SSA) are sensitive to morphology, especially for larger particles with D-mob > 100 nm. Therefore, while using the simplified core-shell representation of BC in global models, the influence of morphology on radiative forcing estimations might not be adequately considered. The Angstrom absorption exponent (AAE) varied from 1.06 up to 3.6 and increased with the fraction of organics (forganics). Measurement results of AAE >> 1 are often misinterpreted as biomass burning aerosol, it was observed that the AAE of purely black carbon particles can be >> 1 in the case of larger BC particles. The values of the absorption enhancement factor (E) via coating were found to be between 1.01 and 3.28 in the visible spectrum. The E was derived from Mie calculations for coated volume equivalent spheres and from MSTM for coated BCFAs. Mie-calculated enhancement factors were found to be larger by a factor of 1.1 to 1.5 than their corresponding values calculated from the MSTM method.
doi_str_mv 10.5194/acp-21-12989-2021
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To understand and quantify how each of these modifications influences the BC radiative forcing, the optical properties of BCFAs are modelled. Owing to the high computational time involved in numerical modelling, there are some gaps in terms of data coverage and knowledge regarding how optical properties of coated BCFAs vary over the range of different factors (size, shape, and composition). This investigation bridged those gaps by following a state-of-the-art description scheme of BCFAs based on morphology, composition, and wavelength. The BCFA optical properties were investigated as a function of the radius of the primary particle (a(o)), fractal dimension (D-f), fraction of organics (f(organics)), wavelength (lambda), and mobility diameter (D-mob). The optical properties are calculated using the multiple-sphere T-matrix (MSTM) method. For the first time, the modelled optical properties of BC are expressed in terms of mobility diameter (Dmob), making the results more relevant and relatable for ambient and laboratory BC studies. Amongst size, morphology, and composition, all the optical properties showed the highest variability with changing size. The cross sections varied from 0.0001 to 0.1 mu m(2) for BCFA D-mob ranging from 24 to 810 nm. It has been shown that MACBC and single-scattering albedo (SSA) are sensitive to morphology, especially for larger particles with D-mob &gt; 100 nm. Therefore, while using the simplified core-shell representation of BC in global models, the influence of morphology on radiative forcing estimations might not be adequately considered. The Angstrom absorption exponent (AAE) varied from 1.06 up to 3.6 and increased with the fraction of organics (forganics). Measurement results of AAE &gt;&gt; 1 are often misinterpreted as biomass burning aerosol, it was observed that the AAE of purely black carbon particles can be &gt;&gt; 1 in the case of larger BC particles. The values of the absorption enhancement factor (E) via coating were found to be between 1.01 and 3.28 in the visible spectrum. The E was derived from Mie calculations for coated volume equivalent spheres and from MSTM for coated BCFAs. Mie-calculated enhancement factors were found to be larger by a factor of 1.1 to 1.5 than their corresponding values calculated from the MSTM method. It is shown that radiative forcings are highly sensitive to modifications in morphology and composition. The black carbon radiative forcing Delta F-TOA (Wm(-2)) decreases up to 61% as the BCFA becomes more compact, indicating that global model calculations should account for changes in morphology. A decrease of more than 50% in Delta F-TOA was observed as the organic content of the particle increased up to 90 %. The changes in the ageing factors (composition and morphology) in tandem result in an overall decrease in the Delta F-TOA. A parameterization scheme for optical properties of BC fractal aggregates was developed, which is applicable for modelling, ambient, and laboratory-based BC studies. The parameterization scheme for the cross sections (extinction, absorption, and scattering), single-scattering albedo (SSA), and asymmetry parameter (g) of pure and coated BCFAs as a function of Dmob were derived from tabulated results of the MSTM method. Spanning an extensive parameter space, the developed parameterization scheme showed promisingly high accuracy up to 98% for the cross sections, 97% for single-scattering albedos (SSAs), and 82% for the asymmetry parameter (g).</description><identifier>ISSN: 1680-7316</identifier><identifier>ISSN: 1680-7324</identifier><identifier>EISSN: 1680-7324</identifier><identifier>DOI: 10.5194/acp-21-12989-2021</identifier><language>eng</language><publisher>GOTTINGEN: Copernicus Gesellschaft Mbh</publisher><subject>Absorption ; Absorption cross sections ; Ageing ; Aggregates ; Aging ; Albedo ; Analysis ; Asymmetry ; Biomass burning ; Black carbon ; Burning ; Carbon ; Carbon particles ; Coatings ; Combustion ; Composition ; Computer applications ; Computing time ; Diameters ; Dimensions ; Environmental Sciences ; Environmental Sciences &amp; Ecology ; Fractal geometry ; Fractals ; Laboratories ; Life Sciences &amp; Biomedicine ; Mathematical models ; Meteorology &amp; Atmospheric Sciences ; Microscopy ; Mobility ; Modelling ; Morphology ; Numerical analysis ; Numerical simulations ; Optical properties ; Parameterization ; Parameters ; Physical Sciences ; Radiative forcing ; Scattering ; Science &amp; Technology ; Visible spectrum ; Wavelength</subject><ispartof>Atmospheric chemistry and physics, 2021-09, Vol.21 (17), p.12989-13010</ispartof><rights>COPYRIGHT 2021 Copernicus GmbH</rights><rights>2021. 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To understand and quantify how each of these modifications influences the BC radiative forcing, the optical properties of BCFAs are modelled. Owing to the high computational time involved in numerical modelling, there are some gaps in terms of data coverage and knowledge regarding how optical properties of coated BCFAs vary over the range of different factors (size, shape, and composition). This investigation bridged those gaps by following a state-of-the-art description scheme of BCFAs based on morphology, composition, and wavelength. The BCFA optical properties were investigated as a function of the radius of the primary particle (a(o)), fractal dimension (D-f), fraction of organics (f(organics)), wavelength (lambda), and mobility diameter (D-mob). The optical properties are calculated using the multiple-sphere T-matrix (MSTM) method. For the first time, the modelled optical properties of BC are expressed in terms of mobility diameter (Dmob), making the results more relevant and relatable for ambient and laboratory BC studies. Amongst size, morphology, and composition, all the optical properties showed the highest variability with changing size. The cross sections varied from 0.0001 to 0.1 mu m(2) for BCFA D-mob ranging from 24 to 810 nm. It has been shown that MACBC and single-scattering albedo (SSA) are sensitive to morphology, especially for larger particles with D-mob &gt; 100 nm. Therefore, while using the simplified core-shell representation of BC in global models, the influence of morphology on radiative forcing estimations might not be adequately considered. The Angstrom absorption exponent (AAE) varied from 1.06 up to 3.6 and increased with the fraction of organics (forganics). Measurement results of AAE &gt;&gt; 1 are often misinterpreted as biomass burning aerosol, it was observed that the AAE of purely black carbon particles can be &gt;&gt; 1 in the case of larger BC particles. The values of the absorption enhancement factor (E) via coating were found to be between 1.01 and 3.28 in the visible spectrum. The E was derived from Mie calculations for coated volume equivalent spheres and from MSTM for coated BCFAs. Mie-calculated enhancement factors were found to be larger by a factor of 1.1 to 1.5 than their corresponding values calculated from the MSTM method. It is shown that radiative forcings are highly sensitive to modifications in morphology and composition. The black carbon radiative forcing Delta F-TOA (Wm(-2)) decreases up to 61% as the BCFA becomes more compact, indicating that global model calculations should account for changes in morphology. A decrease of more than 50% in Delta F-TOA was observed as the organic content of the particle increased up to 90 %. The changes in the ageing factors (composition and morphology) in tandem result in an overall decrease in the Delta F-TOA. A parameterization scheme for optical properties of BC fractal aggregates was developed, which is applicable for modelling, ambient, and laboratory-based BC studies. The parameterization scheme for the cross sections (extinction, absorption, and scattering), single-scattering albedo (SSA), and asymmetry parameter (g) of pure and coated BCFAs as a function of Dmob were derived from tabulated results of the MSTM method. Spanning an extensive parameter space, the developed parameterization scheme showed promisingly high accuracy up to 98% for the cross sections, 97% for single-scattering albedos (SSAs), and 82% for the asymmetry parameter (g).</description><subject>Absorption</subject><subject>Absorption cross sections</subject><subject>Ageing</subject><subject>Aggregates</subject><subject>Aging</subject><subject>Albedo</subject><subject>Analysis</subject><subject>Asymmetry</subject><subject>Biomass burning</subject><subject>Black carbon</subject><subject>Burning</subject><subject>Carbon</subject><subject>Carbon particles</subject><subject>Coatings</subject><subject>Combustion</subject><subject>Composition</subject><subject>Computer applications</subject><subject>Computing time</subject><subject>Diameters</subject><subject>Dimensions</subject><subject>Environmental Sciences</subject><subject>Environmental Sciences &amp; Ecology</subject><subject>Fractal geometry</subject><subject>Fractals</subject><subject>Laboratories</subject><subject>Life Sciences &amp; 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To understand and quantify how each of these modifications influences the BC radiative forcing, the optical properties of BCFAs are modelled. Owing to the high computational time involved in numerical modelling, there are some gaps in terms of data coverage and knowledge regarding how optical properties of coated BCFAs vary over the range of different factors (size, shape, and composition). This investigation bridged those gaps by following a state-of-the-art description scheme of BCFAs based on morphology, composition, and wavelength. The BCFA optical properties were investigated as a function of the radius of the primary particle (a(o)), fractal dimension (D-f), fraction of organics (f(organics)), wavelength (lambda), and mobility diameter (D-mob). The optical properties are calculated using the multiple-sphere T-matrix (MSTM) method. For the first time, the modelled optical properties of BC are expressed in terms of mobility diameter (Dmob), making the results more relevant and relatable for ambient and laboratory BC studies. Amongst size, morphology, and composition, all the optical properties showed the highest variability with changing size. The cross sections varied from 0.0001 to 0.1 mu m(2) for BCFA D-mob ranging from 24 to 810 nm. It has been shown that MACBC and single-scattering albedo (SSA) are sensitive to morphology, especially for larger particles with D-mob &gt; 100 nm. Therefore, while using the simplified core-shell representation of BC in global models, the influence of morphology on radiative forcing estimations might not be adequately considered. The Angstrom absorption exponent (AAE) varied from 1.06 up to 3.6 and increased with the fraction of organics (forganics). Measurement results of AAE &gt;&gt; 1 are often misinterpreted as biomass burning aerosol, it was observed that the AAE of purely black carbon particles can be &gt;&gt; 1 in the case of larger BC particles. The values of the absorption enhancement factor (E) via coating were found to be between 1.01 and 3.28 in the visible spectrum. The E was derived from Mie calculations for coated volume equivalent spheres and from MSTM for coated BCFAs. Mie-calculated enhancement factors were found to be larger by a factor of 1.1 to 1.5 than their corresponding values calculated from the MSTM method. It is shown that radiative forcings are highly sensitive to modifications in morphology and composition. The black carbon radiative forcing Delta F-TOA (Wm(-2)) decreases up to 61% as the BCFA becomes more compact, indicating that global model calculations should account for changes in morphology. A decrease of more than 50% in Delta F-TOA was observed as the organic content of the particle increased up to 90 %. The changes in the ageing factors (composition and morphology) in tandem result in an overall decrease in the Delta F-TOA. A parameterization scheme for optical properties of BC fractal aggregates was developed, which is applicable for modelling, ambient, and laboratory-based BC studies. The parameterization scheme for the cross sections (extinction, absorption, and scattering), single-scattering albedo (SSA), and asymmetry parameter (g) of pure and coated BCFAs as a function of Dmob were derived from tabulated results of the MSTM method. Spanning an extensive parameter space, the developed parameterization scheme showed promisingly high accuracy up to 98% for the cross sections, 97% for single-scattering albedos (SSAs), and 82% for the asymmetry parameter (g).</abstract><cop>GOTTINGEN</cop><pub>Copernicus Gesellschaft Mbh</pub><doi>10.5194/acp-21-12989-2021</doi><tpages>22</tpages><orcidid>https://orcid.org/0000-0002-3761-3957</orcidid><orcidid>https://orcid.org/0000-0002-1704-8292</orcidid><oa>free_for_read</oa></addata></record>
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subjects Absorption
Absorption cross sections
Ageing
Aggregates
Aging
Albedo
Analysis
Asymmetry
Biomass burning
Black carbon
Burning
Carbon
Carbon particles
Coatings
Combustion
Composition
Computer applications
Computing time
Diameters
Dimensions
Environmental Sciences
Environmental Sciences & Ecology
Fractal geometry
Fractals
Laboratories
Life Sciences & Biomedicine
Mathematical models
Meteorology & Atmospheric Sciences
Microscopy
Mobility
Modelling
Morphology
Numerical analysis
Numerical simulations
Optical properties
Parameterization
Parameters
Physical Sciences
Radiative forcing
Scattering
Science & Technology
Visible spectrum
Wavelength
title Optical properties of coated black carbon aggregates: numerical simulations, radiative forcing estimates, and size-resolved parameterization scheme
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