Exploring the use of a column model for the characterization of microphysical processes in warm rain: Results from a homogeneous rainshaft model

O. P. Prat; A. P. Barros

doi:10.5194/adgeo-10-145-2007

Exploring the use of a column model for the characterization of microphysical processes in warm rain: Results from a homogeneous rainshaft model

O. P. Prat
, A. P. Barros

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

Abstract

A study of the evolution of raindrop spectra (raindrop size distribution, DSD) between cloud base and the ground surface was conducted using a column model of stochastic coalescense-breakup dynamics. Numerical results show that, under steady-state boundary conditions (i.e. constant rainfall rate and DSD at the top of the rainshaft), the equilibrium DSD is achieved only for high rain rates produced by midlevel or higher clouds and after long simulation times (∼ 30 min or greater). Because these conditions are not typical of most rainfall, the results suggest that the theoretical equilibrium DSD might not be attainable for the duration of individual rain events, and thus DSD observations from field experiments should be analyzed conditional on the specific storm environment under which they were obtained.

Original language	English (US)
Pages (from-to)	145-152
Number of pages	8
Journal	Advances in Geosciences
Volume	10
DOIs	https://doi.org/10.5194/adgeo-10-145-2007
State	Published - 2007
Externally published	Yes

ASJC Scopus subject areas

Earth and Planetary Sciences (miscellaneous)
Space and Planetary Science

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10.5194/adgeo-10-145-2007

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abstract = "A study of the evolution of raindrop spectra (raindrop size distribution, DSD) between cloud base and the ground surface was conducted using a column model of stochastic coalescense-breakup dynamics. Numerical results show that, under steady-state boundary conditions (i.e. constant rainfall rate and DSD at the top of the rainshaft), the equilibrium DSD is achieved only for high rain rates produced by midlevel or higher clouds and after long simulation times (∼ 30 min or greater). Because these conditions are not typical of most rainfall, the results suggest that the theoretical equilibrium DSD might not be attainable for the duration of individual rain events, and thus DSD observations from field experiments should be analyzed conditional on the specific storm environment under which they were obtained.",

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Y1 - 2007

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AB - A study of the evolution of raindrop spectra (raindrop size distribution, DSD) between cloud base and the ground surface was conducted using a column model of stochastic coalescense-breakup dynamics. Numerical results show that, under steady-state boundary conditions (i.e. constant rainfall rate and DSD at the top of the rainshaft), the equilibrium DSD is achieved only for high rain rates produced by midlevel or higher clouds and after long simulation times (∼ 30 min or greater). Because these conditions are not typical of most rainfall, the results suggest that the theoretical equilibrium DSD might not be attainable for the duration of individual rain events, and thus DSD observations from field experiments should be analyzed conditional on the specific storm environment under which they were obtained.

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JO - Advances in Geosciences

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Exploring the use of a column model for the characterization of microphysical processes in warm rain: Results from a homogeneous rainshaft model

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