Droplet nucleation and growth in orographic clouds in relation to the aerosol population

Bengt G. Martinsson; Göran Frank; Sven Inge Cederfelt; Erik Swietlicki; Olle H. Berg; Jingchuan Zhou; Keith N. Bower; Carl Bradbury; Wolfram Birmili; Frank Stratmann; Manfred Wendisch; Alfred Wiedensohler; Brett A. Yuskiewicz

doi:10.1016/S0169-8095(98)00108-2

Droplet nucleation and growth in orographic clouds in relation to the aerosol population

Bengt G. Martinsson, Göran Frank, Sven Inge Cederfelt, Erik Swietlicki, Olle H. Berg, Jingchuan Zhou, Keith N. Bower, Carl Bradbury, Wolfram Birmili, Frank Stratmann, Manfred Wendisch, Alfred Wiedensohler, Brett A. Yuskiewicz

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

Abstract

The formation and development of orographic clouds was studied in a field experiment comprising several measurement sites at a mountain ridge. The influence of the aerosol population present on the cloud microstructure was studied in relation to the dynamics in the cloud formation. Droplet nucleation scavenging was investigated by the introduction of a non-dimensional particle diameter related to the process, and it was found that the scavenging rose rapidly in a relatively narrow particle size interval. The size dependency of the scavenging could partly be explained by external mixture of the aerosol. The large particles in the cloud interstitial aerosol was found to be of a chemical nature which allows for only a very weak uptake of water, implying that the chemical composition of these particles rather than entrainment of dry air prevented the droplet nucleation. The aerosol particle number concentration was found to strongly influence the cloud microstructure. Droplet number concentrations up to approximately 2000 cm^-3 were observed together with a substantially reduced effective droplet diameter. The observed effect of elevated particle number concentrations in orographic clouds was generalised to the climatologically more important stratiform clouds by the use of a cloud model. It was found that the microstructure of stratiform clouds was strongly dependent on the aerosol population present as well on the dynamics in the cloud formation.

Original language	English
Pages (from-to)	289-315
Number of pages	27
Journal	Atmospheric Research
Volume	50
Issue number	3-4
DOIs	https://doi.org/10.1016/S0169-8095(98)00108-2
Publication status	Published - 1999 Mar 1

Subject classification (UKÄ)

Meteorology and Atmospheric Sciences

Free keywords

Aerosol
Climate
Cloud
Microphysics
Number concentration
Scavenging
Solute concentration

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/S0169-8095(98)00108-2

Cite this

Martinsson, B. G., Frank, G., Cederfelt, S. I., Swietlicki, E., Berg, O. H., Zhou, J., Bower, K. N., Bradbury, C., Birmili, W., Stratmann, F., Wendisch, M., Wiedensohler, A., & Yuskiewicz, B. A. (1999). Droplet nucleation and growth in orographic clouds in relation to the aerosol population. Atmospheric Research, 50(3-4), 289-315. https://doi.org/10.1016/S0169-8095(98)00108-2

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abstract = "The formation and development of orographic clouds was studied in a field experiment comprising several measurement sites at a mountain ridge. The influence of the aerosol population present on the cloud microstructure was studied in relation to the dynamics in the cloud formation. Droplet nucleation scavenging was investigated by the introduction of a non-dimensional particle diameter related to the process, and it was found that the scavenging rose rapidly in a relatively narrow particle size interval. The size dependency of the scavenging could partly be explained by external mixture of the aerosol. The large particles in the cloud interstitial aerosol was found to be of a chemical nature which allows for only a very weak uptake of water, implying that the chemical composition of these particles rather than entrainment of dry air prevented the droplet nucleation. The aerosol particle number concentration was found to strongly influence the cloud microstructure. Droplet number concentrations up to approximately 2000 cm-3 were observed together with a substantially reduced effective droplet diameter. The observed effect of elevated particle number concentrations in orographic clouds was generalised to the climatologically more important stratiform clouds by the use of a cloud model. It was found that the microstructure of stratiform clouds was strongly dependent on the aerosol population present as well on the dynamics in the cloud formation.",

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author = "Martinsson, {Bengt G.} and G{\"o}ran Frank and Cederfelt, {Sven Inge} and Erik Swietlicki and Berg, {Olle H.} and Jingchuan Zhou and Bower, {Keith N.} and Carl Bradbury and Wolfram Birmili and Frank Stratmann and Manfred Wendisch and Alfred Wiedensohler and Yuskiewicz, {Brett A.}",

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AU - Martinsson, Bengt G.

AU - Frank, Göran

AU - Cederfelt, Sven Inge

AU - Swietlicki, Erik

AU - Berg, Olle H.

AU - Zhou, Jingchuan

AU - Bower, Keith N.

AU - Bradbury, Carl

AU - Birmili, Wolfram

AU - Stratmann, Frank

AU - Wendisch, Manfred

AU - Wiedensohler, Alfred

AU - Yuskiewicz, Brett A.

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N2 - The formation and development of orographic clouds was studied in a field experiment comprising several measurement sites at a mountain ridge. The influence of the aerosol population present on the cloud microstructure was studied in relation to the dynamics in the cloud formation. Droplet nucleation scavenging was investigated by the introduction of a non-dimensional particle diameter related to the process, and it was found that the scavenging rose rapidly in a relatively narrow particle size interval. The size dependency of the scavenging could partly be explained by external mixture of the aerosol. The large particles in the cloud interstitial aerosol was found to be of a chemical nature which allows for only a very weak uptake of water, implying that the chemical composition of these particles rather than entrainment of dry air prevented the droplet nucleation. The aerosol particle number concentration was found to strongly influence the cloud microstructure. Droplet number concentrations up to approximately 2000 cm-3 were observed together with a substantially reduced effective droplet diameter. The observed effect of elevated particle number concentrations in orographic clouds was generalised to the climatologically more important stratiform clouds by the use of a cloud model. It was found that the microstructure of stratiform clouds was strongly dependent on the aerosol population present as well on the dynamics in the cloud formation.

AB - The formation and development of orographic clouds was studied in a field experiment comprising several measurement sites at a mountain ridge. The influence of the aerosol population present on the cloud microstructure was studied in relation to the dynamics in the cloud formation. Droplet nucleation scavenging was investigated by the introduction of a non-dimensional particle diameter related to the process, and it was found that the scavenging rose rapidly in a relatively narrow particle size interval. The size dependency of the scavenging could partly be explained by external mixture of the aerosol. The large particles in the cloud interstitial aerosol was found to be of a chemical nature which allows for only a very weak uptake of water, implying that the chemical composition of these particles rather than entrainment of dry air prevented the droplet nucleation. The aerosol particle number concentration was found to strongly influence the cloud microstructure. Droplet number concentrations up to approximately 2000 cm-3 were observed together with a substantially reduced effective droplet diameter. The observed effect of elevated particle number concentrations in orographic clouds was generalised to the climatologically more important stratiform clouds by the use of a cloud model. It was found that the microstructure of stratiform clouds was strongly dependent on the aerosol population present as well on the dynamics in the cloud formation.

KW - Aerosol

KW - Climate

KW - Cloud

KW - Microphysics

KW - Number concentration

KW - Scavenging

KW - Solute concentration

U2 - 10.1016/S0169-8095(98)00108-2

DO - 10.1016/S0169-8095(98)00108-2

M3 - Article

AN - SCOPUS:6744227921

SN - 0169-8095

VL - 50

SP - 289

EP - 315

JO - Atmospheric Research

JF - Atmospheric Research

IS - 3-4

ER -

Droplet nucleation and growth in orographic clouds in relation to the aerosol population

Abstract

Subject classification (UKÄ)

Free keywords

UN SDGs

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