The role of 1-D and 3-D radiative heating in the organization of shallow cumulus convection and the formation of cloud streets

The formation of shallow cumulus cloud streets was historically attributed primarily to dynamics. Here, we focus on the interaction between radiatively induced surface heterogeneities and the resulting patterns in the flow. Our results suggest that solar radiative heating has the potential to...

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Main Authors: F. Jakub, B. Mayer
Format: Article
Language:English
Published: Copernicus Publications 2017-11-01
Series:Atmospheric Chemistry and Physics
Online Access:https://www.atmos-chem-phys.net/17/13317/2017/acp-17-13317-2017.pdf
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spelling doaj-127d123d7f944515a42711668070dd9f2020-11-24T22:51:07ZengCopernicus PublicationsAtmospheric Chemistry and Physics1680-73161680-73242017-11-0117133171332710.5194/acp-17-13317-2017The role of 1-D and 3-D radiative heating in the organization of shallow cumulus convection and the formation of cloud streetsF. Jakub0B. Mayer1Meteorological Institute, Ludwig Maximilian Universität München, LMU, Munich, GermanyMeteorological Institute, Ludwig Maximilian Universität München, LMU, Munich, GermanyThe formation of shallow cumulus cloud streets was historically attributed primarily to dynamics. Here, we focus on the interaction between radiatively induced surface heterogeneities and the resulting patterns in the flow. Our results suggest that solar radiative heating has the potential to organize clouds perpendicular to the sun's incidence angle. <br><br> To quantify the extent of organization, we performed a high-resolution large-eddy simulation (LES) parameter study. We varied the horizontal wind speed, the surface heat capacity, the solar zenith and azimuth angles, and radiative transfer parameterizations (1-D and 3-D). As a quantitative measure we introduce a simple algorithm that provides a scalar quantity for the degree of organization and the alignment. We find that, even in the absence of a horizontal wind, 3-D radiative transfer produces cloud streets perpendicular to the sun's incident direction, whereas the 1-D approximation or constant surface fluxes produce randomly positioned circular clouds. Our reasoning for the enhancement or reduction of organization is the geometric position of the cloud's shadow and its corresponding surface fluxes. Furthermore, when increasing horizontal wind speeds to 5 or 10 m s<sup>−1</sup>, we observe the development of dynamically induced cloud streets. If, in addition, solar radiation illuminates the surface beneath the cloud, i.e., when the sun is positioned orthogonally to the mean wind field and the solar zenith angle is larger than 20°, the cloud-radiative feedback has the potential to significantly enhance the tendency to organize in cloud streets. In contrast, in the case of the 1-D approximation (or overhead sun), the tendency to organize is weaker or even prohibited because the shadow is cast directly beneath the cloud. In a land-surface-type situation, we find the organization of convection happening on a timescale of half an hour. The radiative feedback, which creates surface heterogeneities, is generally diminished for large surface heat capacities. We therefore expect radiative feedbacks to be strongest over land surfaces and weaker over the ocean. Given the results of this study we expect that simulations including shallow cumulus convection will have difficulties producing cloud streets if they employ 1-D radiative transfer solvers or may need unrealistically high wind speeds to excite cloud street organization.https://www.atmos-chem-phys.net/17/13317/2017/acp-17-13317-2017.pdf
collection DOAJ
language English
format Article
sources DOAJ
author F. Jakub
B. Mayer
spellingShingle F. Jakub
B. Mayer
The role of 1-D and 3-D radiative heating in the organization of shallow cumulus convection and the formation of cloud streets
Atmospheric Chemistry and Physics
author_facet F. Jakub
B. Mayer
author_sort F. Jakub
title The role of 1-D and 3-D radiative heating in the organization of shallow cumulus convection and the formation of cloud streets
title_short The role of 1-D and 3-D radiative heating in the organization of shallow cumulus convection and the formation of cloud streets
title_full The role of 1-D and 3-D radiative heating in the organization of shallow cumulus convection and the formation of cloud streets
title_fullStr The role of 1-D and 3-D radiative heating in the organization of shallow cumulus convection and the formation of cloud streets
title_full_unstemmed The role of 1-D and 3-D radiative heating in the organization of shallow cumulus convection and the formation of cloud streets
title_sort role of 1-d and 3-d radiative heating in the organization of shallow cumulus convection and the formation of cloud streets
publisher Copernicus Publications
series Atmospheric Chemistry and Physics
issn 1680-7316
1680-7324
publishDate 2017-11-01
description The formation of shallow cumulus cloud streets was historically attributed primarily to dynamics. Here, we focus on the interaction between radiatively induced surface heterogeneities and the resulting patterns in the flow. Our results suggest that solar radiative heating has the potential to organize clouds perpendicular to the sun's incidence angle. <br><br> To quantify the extent of organization, we performed a high-resolution large-eddy simulation (LES) parameter study. We varied the horizontal wind speed, the surface heat capacity, the solar zenith and azimuth angles, and radiative transfer parameterizations (1-D and 3-D). As a quantitative measure we introduce a simple algorithm that provides a scalar quantity for the degree of organization and the alignment. We find that, even in the absence of a horizontal wind, 3-D radiative transfer produces cloud streets perpendicular to the sun's incident direction, whereas the 1-D approximation or constant surface fluxes produce randomly positioned circular clouds. Our reasoning for the enhancement or reduction of organization is the geometric position of the cloud's shadow and its corresponding surface fluxes. Furthermore, when increasing horizontal wind speeds to 5 or 10 m s<sup>−1</sup>, we observe the development of dynamically induced cloud streets. If, in addition, solar radiation illuminates the surface beneath the cloud, i.e., when the sun is positioned orthogonally to the mean wind field and the solar zenith angle is larger than 20°, the cloud-radiative feedback has the potential to significantly enhance the tendency to organize in cloud streets. In contrast, in the case of the 1-D approximation (or overhead sun), the tendency to organize is weaker or even prohibited because the shadow is cast directly beneath the cloud. In a land-surface-type situation, we find the organization of convection happening on a timescale of half an hour. The radiative feedback, which creates surface heterogeneities, is generally diminished for large surface heat capacities. We therefore expect radiative feedbacks to be strongest over land surfaces and weaker over the ocean. Given the results of this study we expect that simulations including shallow cumulus convection will have difficulties producing cloud streets if they employ 1-D radiative transfer solvers or may need unrealistically high wind speeds to excite cloud street organization.
url https://www.atmos-chem-phys.net/17/13317/2017/acp-17-13317-2017.pdf
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