Modelling the mineralogical composition and solubility of mineral dust in the Mediterranean area with CHIMERE 2017r4

Laurent Menut; Guillaume Siour; Bertrand Bessagnet; Florian Couvidat; Emilie Journet; Yves Balkanski; Karine Desboeufs

doi:10.5194/gmd-13-2051-2020

Modelling the mineralogical composition and solubility of mineral dust in the Mediterranean area with CHIMERE 2017r4

Laurent Menut
, Guillaume Siour
, Bertrand Bessagnet
, Florian Couvidat
, Emilie Journet
, Yves Balkanski
, Karine Desboeufs

Research output: Contribution to journal › Article › peer-review

Abstract

Modelling of mineral dust is often done using one single mean species. But for biogeochemical studies, it could be useful to access to a more detailed information on differentiated mineral species and the associated chemical composition. Differentiating between mineral species would also induce different optical properties and densities and then different radiative impact, transport and deposition. In this study, the mineralogical differentiation is implemented in the CHIMERE regional chemistry-transport model, by using global databases. The results show that this implementation does not change the results much in terms of aerosol optical depth, surface concentrations and deposition fluxes. But the information on mineralogy, with a high spatial (a few kilometres) and temporal (1 h) resolution, is now available and is ready to be used for future biogeochemical studies.

Original language	English
Pages (from-to)	2051-2071
Number of pages	21
Journal	Geoscientific Model Development
Volume	13
Issue number	4
DOIs	https://doi.org/10.5194/gmd-13-2051-2020
Publication status	Published - 24 Apr 2020
Externally published	Yes

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title = "Modelling the mineralogical composition and solubility of mineral dust in the Mediterranean area with CHIMERE 2017r4",

abstract = "Modelling of mineral dust is often done using one single mean species. But for biogeochemical studies, it could be useful to access to a more detailed information on differentiated mineral species and the associated chemical composition. Differentiating between mineral species would also induce different optical properties and densities and then different radiative impact, transport and deposition. In this study, the mineralogical differentiation is implemented in the CHIMERE regional chemistry-transport model, by using global databases. The results show that this implementation does not change the results much in terms of aerosol optical depth, surface concentrations and deposition fluxes. But the information on mineralogy, with a high spatial (a few kilometres) and temporal (1\ h) resolution, is now available and is ready to be used for future biogeochemical studies.",

author = "Laurent Menut and Guillaume Siour and Bertrand Bessagnet and Florian Couvidat and Emilie Journet and Yves Balkanski and Karine Desboeufs",

year = "2020",

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T1 - Modelling the mineralogical composition and solubility of mineral dust in the Mediterranean area with CHIMERE 2017r4

AU - Menut, Laurent

AU - Siour, Guillaume

AU - Bessagnet, Bertrand

AU - Couvidat, Florian

AU - Journet, Emilie

AU - Balkanski, Yves

AU - Desboeufs, Karine

PY - 2020/4/24

Y1 - 2020/4/24

N2 - Modelling of mineral dust is often done using one single mean species. But for biogeochemical studies, it could be useful to access to a more detailed information on differentiated mineral species and the associated chemical composition. Differentiating between mineral species would also induce different optical properties and densities and then different radiative impact, transport and deposition. In this study, the mineralogical differentiation is implemented in the CHIMERE regional chemistry-transport model, by using global databases. The results show that this implementation does not change the results much in terms of aerosol optical depth, surface concentrations and deposition fluxes. But the information on mineralogy, with a high spatial (a few kilometres) and temporal (1 h) resolution, is now available and is ready to be used for future biogeochemical studies.

AB - Modelling of mineral dust is often done using one single mean species. But for biogeochemical studies, it could be useful to access to a more detailed information on differentiated mineral species and the associated chemical composition. Differentiating between mineral species would also induce different optical properties and densities and then different radiative impact, transport and deposition. In this study, the mineralogical differentiation is implemented in the CHIMERE regional chemistry-transport model, by using global databases. The results show that this implementation does not change the results much in terms of aerosol optical depth, surface concentrations and deposition fluxes. But the information on mineralogy, with a high spatial (a few kilometres) and temporal (1 h) resolution, is now available and is ready to be used for future biogeochemical studies.

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DO - 10.5194/gmd-13-2051-2020

M3 - Article

AN - SCOPUS:85084242044

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SP - 2051

EP - 2071

JO - Geoscientific Model Development

JF - Geoscientific Model Development

IS - 4

ER -

Modelling the mineralogical composition and solubility of mineral dust in the Mediterranean area with CHIMERE 2017r4

Abstract

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