Inferring iron-oxide species content in ...
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Article dans une revue scientifique: Article original
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Title :
Inferring iron-oxide species content in atmospheric mineral dust from DSCOVR EPIC observations
Author(s) :
Go, Sujung [Auteur]
University of Maryland [Baltimore County] [UMBC]
NASA Goddard Space Flight Center [GSFC]
Lyapustin, Alexei [Auteur]
NASA Goddard Space Flight Center [GSFC]
Schuster, Gregory L. [Auteur]
NASA Langley Research Center [Hampton] [LaRC]
Choi, Myungje [Auteur]
University of Maryland [Baltimore County] [UMBC]
NASA Goddard Space Flight Center [GSFC]
Ginoux, Paul [Auteur]
NOAA Geophysical Fluid Dynamics Laboratory [GFDL]
Chin, Mian [Auteur]
NASA Goddard Space Flight Center [GSFC]
Kalashnikova, Olga [Auteur]
Jet Propulsion Laboratory [JPL]
Doubovik, Oleg [Auteur]
Laboratoire d'Optique Atmosphérique (LOA) - UMR 8518
Kim, Jhoon [Auteur]
Yonsei University
Da Silva, Arlindo [Auteur]
NASA Goddard Space Flight Center [GSFC]
Holben, Brent [Auteur]
NASA Goddard Space Flight Center [GSFC]
Reid, Jeffrey S. [Auteur]
Naval Research Laboratory [NRL]
University of Maryland [Baltimore County] [UMBC]
NASA Goddard Space Flight Center [GSFC]
Lyapustin, Alexei [Auteur]
NASA Goddard Space Flight Center [GSFC]
Schuster, Gregory L. [Auteur]
NASA Langley Research Center [Hampton] [LaRC]
Choi, Myungje [Auteur]
University of Maryland [Baltimore County] [UMBC]
NASA Goddard Space Flight Center [GSFC]
Ginoux, Paul [Auteur]
NOAA Geophysical Fluid Dynamics Laboratory [GFDL]
Chin, Mian [Auteur]
NASA Goddard Space Flight Center [GSFC]
Kalashnikova, Olga [Auteur]
Jet Propulsion Laboratory [JPL]
Doubovik, Oleg [Auteur]
Laboratoire d'Optique Atmosphérique (LOA) - UMR 8518
Kim, Jhoon [Auteur]
Yonsei University
Da Silva, Arlindo [Auteur]
NASA Goddard Space Flight Center [GSFC]
Holben, Brent [Auteur]
NASA Goddard Space Flight Center [GSFC]
Reid, Jeffrey S. [Auteur]
Naval Research Laboratory [NRL]
Journal title :
Atmospheric Chemistry and Physics
Abbreviated title :
Atmos. Chem. Phys.
Volume number :
22
Pages :
-
Publication date :
2022-02-13
ISSN :
1680-7316
HAL domain(s) :
Planète et Univers [physics]/Océan, Atmosphère
English abstract : [en]
The iron-oxide content of dust in the atmosphere and most notably its apportionment between hematite (α-Fe2O3) and goethite (α-FeOOH) are key determinants in quantifying dust's light absorption, its top of atmosphere ...
Show more >The iron-oxide content of dust in the atmosphere and most notably its apportionment between hematite (α-Fe2O3) and goethite (α-FeOOH) are key determinants in quantifying dust's light absorption, its top of atmosphere ultraviolet (UV) radiances used for dust monitoring, and ultimately shortwave dust direct radiative effects (DREs). Hematite and goethite column mass concentrations and iron-oxide mass fractions of total dust mass concentration were retrieved from the Deep Space Climate Observatory (DSCOVR) Earth Polychromatic Imaging Camera (EPIC) measurements in the ultraviolet-visible (UV-Vis) channels. The retrievals were performed for dust-identified aerosol plumes over land using aerosol optical depth (AOD) and the spectral imaginary refractive index provided by the Multi-Angle Implementation of Atmospheric Correction (MAIAC) algorithm over six continental regions (North America, North Africa, West Asia, Central Asia, East Asia, and Australia). The dust particles are represented as an internal mixture of non-absorbing host and absorbing hematite and goethite. We use the Maxwell Garnett effective medium approximation with carefully selected complex refractive indices of hematite and goethite that produce mass fractions of iron-oxide species consistent with in situ values found in the literature to derive the hematite and goethite volumetric/mass concentrations from MAIAC EPIC products. We compared the retrieved hematite and goethite concentrations with in situ dust aerosol mineralogical content measurements, as well as with published data. Our data display variations within the published range of hematite, goethite, and iron-oxide mass fractions for pure-mineral-dust cases. A specific analysis is presented for 15 sites over the main dust-source regions. Sites in the central Sahara, Sahel, and Middle East exhibit a greater temporal variability of iron oxides relative to other sites. The Niger site (13.52∘ N, 2.63∘ E) is dominated by goethite over the Harmattan season with a median of ∼ 2 weight percentage (wt %) of iron oxide. The Saudi Arabia site (27.49∘ N, 41.98∘ E) over the Middle East also exhibited a surge of goethite content with the beginning of the shamal season. The Sahel dust is richer in iron oxide than Saharan and northern China dust except in summer. The Bodélé Depression area shows a distinctively lower iron-oxide concentration (∼ 1 wt %) throughout the year. Finally, we show that EPIC data allow the constraining of the hematite refractive index. Specifically, we select 5 out of 13 different hematite refractive indices that are widely variable in published laboratory studies by constraining the iron-oxide mass ratio to the known measured values. The provided climatology of hematite and goethite mass fractions across the main dust regions of Earth will be useful for dust shortwave DRE studies and climate modeling.Show less >
Show more >The iron-oxide content of dust in the atmosphere and most notably its apportionment between hematite (α-Fe2O3) and goethite (α-FeOOH) are key determinants in quantifying dust's light absorption, its top of atmosphere ultraviolet (UV) radiances used for dust monitoring, and ultimately shortwave dust direct radiative effects (DREs). Hematite and goethite column mass concentrations and iron-oxide mass fractions of total dust mass concentration were retrieved from the Deep Space Climate Observatory (DSCOVR) Earth Polychromatic Imaging Camera (EPIC) measurements in the ultraviolet-visible (UV-Vis) channels. The retrievals were performed for dust-identified aerosol plumes over land using aerosol optical depth (AOD) and the spectral imaginary refractive index provided by the Multi-Angle Implementation of Atmospheric Correction (MAIAC) algorithm over six continental regions (North America, North Africa, West Asia, Central Asia, East Asia, and Australia). The dust particles are represented as an internal mixture of non-absorbing host and absorbing hematite and goethite. We use the Maxwell Garnett effective medium approximation with carefully selected complex refractive indices of hematite and goethite that produce mass fractions of iron-oxide species consistent with in situ values found in the literature to derive the hematite and goethite volumetric/mass concentrations from MAIAC EPIC products. We compared the retrieved hematite and goethite concentrations with in situ dust aerosol mineralogical content measurements, as well as with published data. Our data display variations within the published range of hematite, goethite, and iron-oxide mass fractions for pure-mineral-dust cases. A specific analysis is presented for 15 sites over the main dust-source regions. Sites in the central Sahara, Sahel, and Middle East exhibit a greater temporal variability of iron oxides relative to other sites. The Niger site (13.52∘ N, 2.63∘ E) is dominated by goethite over the Harmattan season with a median of ∼ 2 weight percentage (wt %) of iron oxide. The Saudi Arabia site (27.49∘ N, 41.98∘ E) over the Middle East also exhibited a surge of goethite content with the beginning of the shamal season. The Sahel dust is richer in iron oxide than Saharan and northern China dust except in summer. The Bodélé Depression area shows a distinctively lower iron-oxide concentration (∼ 1 wt %) throughout the year. Finally, we show that EPIC data allow the constraining of the hematite refractive index. Specifically, we select 5 out of 13 different hematite refractive indices that are widely variable in published laboratory studies by constraining the iron-oxide mass ratio to the known measured values. The provided climatology of hematite and goethite mass fractions across the main dust regions of Earth will be useful for dust shortwave DRE studies and climate modeling.Show less >
Language :
Anglais
Audience :
Internationale
Popular science :
Non
Administrative institution(s) :
Université de Lille
CNRS
CNRS
Collections :
Submission date :
2024-01-16T22:39:41Z
2024-02-16T10:26:12Z
2024-02-16T10:26:12Z
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