New explicit formulae for the settling speed of prolate spheroids in the atmosphere: Theoretical background and implementation in AerSett v2.0.2

Sylvain Mailler; Sotirios Mallios; Arineh Cholakian; Vassilis Amiridis; Laurent Menut; Romain Pennel

doi:10.5194/gmd-17-5641-2024

New explicit formulae for the settling speed of prolate spheroids in the atmosphere: Theoretical background and implementation in AerSett v2.0.2

Sylvain Mailler
, Sotirios Mallios
, Arineh Cholakian
, Vassilis Amiridis
, Laurent Menut
, Romain Pennel

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

Abstract

We propose two explicit expressions to calculate the settling speed of solid atmospheric particles with prolate spheroidal shapes under the hypothesis of horizontal and vertical orientation. The first formulation is based on theoretical arguments only. The second method, valid for particles with mass median diameter up to 1000 μm, is based on recent heuristic drag expressions based on numeric simulations. We show that these two formulations show equivalent results within 2 % for deq≤100 μm and within 10 % for particles with deq≤500 μm falling with a horizontal orientation, showing that the first, more simple, method is suitable for virtually all atmospheric aerosols, provided their shape can be adequately described as a prolate spheroid. Finally, in order to facilitate the use of our results in chemistry transport models, we provide an implementation of the first of these methods in AerSett v2.0.2, a module written in Fortran.

Original language	English
Pages (from-to)	5641-5655
Number of pages	15
Journal	Geoscientific Model Development
Volume	17
Issue number	14
DOIs	https://doi.org/10.5194/gmd-17-5641-2024
Publication status	Published - 26 Jul 2024
Externally published	Yes

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title = "New explicit formulae for the settling speed of prolate spheroids in the atmosphere: Theoretical background and implementation in AerSett v2.0.2",

abstract = "We propose two explicit expressions to calculate the settling speed of solid atmospheric particles with prolate spheroidal shapes under the hypothesis of horizontal and vertical orientation. The first formulation is based on theoretical arguments only. The second method, valid for particles with mass median diameter up to 1000 μm, is based on recent heuristic drag expressions based on numeric simulations. We show that these two formulations show equivalent results within 2 \% for deq≤100 μm and within 10 \% for particles with deq≤500 μm falling with a horizontal orientation, showing that the first, more simple, method is suitable for virtually all atmospheric aerosols, provided their shape can be adequately described as a prolate spheroid. Finally, in order to facilitate the use of our results in chemistry transport models, we provide an implementation of the first of these methods in AerSett v2.0.2, a module written in Fortran.",

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T2 - Theoretical background and implementation in AerSett v2.0.2

AU - Mailler, Sylvain

AU - Mallios, Sotirios

AU - Cholakian, Arineh

AU - Amiridis, Vassilis

AU - Menut, Laurent

AU - Pennel, Romain

PY - 2024/7/26

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N2 - We propose two explicit expressions to calculate the settling speed of solid atmospheric particles with prolate spheroidal shapes under the hypothesis of horizontal and vertical orientation. The first formulation is based on theoretical arguments only. The second method, valid for particles with mass median diameter up to 1000 μm, is based on recent heuristic drag expressions based on numeric simulations. We show that these two formulations show equivalent results within 2 % for deq≤100 μm and within 10 % for particles with deq≤500 μm falling with a horizontal orientation, showing that the first, more simple, method is suitable for virtually all atmospheric aerosols, provided their shape can be adequately described as a prolate spheroid. Finally, in order to facilitate the use of our results in chemistry transport models, we provide an implementation of the first of these methods in AerSett v2.0.2, a module written in Fortran.

AB - We propose two explicit expressions to calculate the settling speed of solid atmospheric particles with prolate spheroidal shapes under the hypothesis of horizontal and vertical orientation. The first formulation is based on theoretical arguments only. The second method, valid for particles with mass median diameter up to 1000 μm, is based on recent heuristic drag expressions based on numeric simulations. We show that these two formulations show equivalent results within 2 % for deq≤100 μm and within 10 % for particles with deq≤500 μm falling with a horizontal orientation, showing that the first, more simple, method is suitable for virtually all atmospheric aerosols, provided their shape can be adequately described as a prolate spheroid. Finally, in order to facilitate the use of our results in chemistry transport models, we provide an implementation of the first of these methods in AerSett v2.0.2, a module written in Fortran.

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ER -

New explicit formulae for the settling speed of prolate spheroids in the atmosphere: Theoretical background and implementation in AerSett v2.0.2

Abstract

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