High-resolution measurement of cloud microphysics and turbulence at a mountaintop station

High-resolution measurement of cloud microphysics and turbulence at a mountaintop station

Mountain research stations are advantageous not only for long-term sampling of cloud properties but also for measurements that are prohibitively difficult to perform on airborne platforms due to the large true air speed or adverse factors such as weight and complexity of the equipment necessary. Som...

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Main Authors: H. Siebert, R. A. Shaw, J. Ditas, T. Schmeissner, S. P. Malinowski, E. Bodenschatz, H. Xu
Format: Article
Language:English
Published: Copernicus Publications 2015-08-01
Series:Atmospheric Measurement Techniques
Online Access:http://www.atmos-meas-tech.net/8/3219/2015/amt-8-3219-2015.pdf
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spelling doaj-3f8bd5f873ad495e81050f015a244c3e2020-11-24T22:55:03ZengCopernicus PublicationsAtmospheric Measurement Techniques1867-13811867-85482015-08-01883219322810.5194/amt-8-3219-2015High-resolution measurement of cloud microphysics and turbulence at a mountaintop stationH. Siebert0R. A. Shaw1J. Ditas2T. Schmeissner3S. P. Malinowski4E. Bodenschatz5H. Xu6Leibniz Institute for Tropospheric Research, Leipzig, GermanyDepartment of Physics, Michigan Technological University, Michigan, USAMax Planck Institute for Chemistry, Mainz, GermanyLeibniz Institute for Tropospheric Research, Leipzig, GermanyInstitute of Geophysics, Faculty of Physics, University of Warsaw, Warsaw, PolandMax Planck Institute for Dynamics and Self-Organization (MPIDS), Göttingen, GermanyMax Planck Institute for Dynamics and Self-Organization (MPIDS), Göttingen, GermanyMountain research stations are advantageous not only for long-term sampling of cloud properties but also for measurements that are prohibitively difficult to perform on airborne platforms due to the large true air speed or adverse factors such as weight and complexity of the equipment necessary. Some cloud–turbulence measurements, especially Lagrangian in nature, fall into this category. We report results from simultaneous, high-resolution and collocated measurements of cloud microphysical and turbulence properties during several warm cloud events at the Umweltforschungsstation Schneefernerhaus (UFS) on Zugspitze in the German Alps. The data gathered were found to be representative of observations made with similar instrumentation in free clouds. The observed turbulence shared all features known for high-Reynolds-number flows: it exhibited approximately Gaussian fluctuations for all three velocity components, a clearly defined inertial subrange following Kolmogorov scaling (power spectrum, and second- and third-order Eulerian structure functions), and highly intermittent velocity gradients, as well as approximately lognormal kinetic energy dissipation rates. The clouds were observed to have liquid water contents on the order of 1 g m<sup>−3</sup> and size distributions typical of continental clouds, sometimes exhibiting long positive tails indicative of large drop production through turbulent mixing or coalescence growth. Dimensionless parameters relevant to cloud–turbulence interactions, the Stokes number and settling parameter are in the range typically observed in atmospheric clouds. Observed fluctuations in droplet number concentration and diameter suggest a preference for inhomogeneous mixing. Finally, enhanced variance in liquid water content fluctuations is observed at high frequencies, and the scale break occurs at a value consistent with the independently estimated phase relaxation time from microphysical measurements.http://www.atmos-meas-tech.net/8/3219/2015/amt-8-3219-2015.pdf
collection DOAJ
language English
format Article
sources DOAJ
author H. Siebert
R. A. Shaw
J. Ditas
T. Schmeissner
S. P. Malinowski
E. Bodenschatz
H. Xu
spellingShingle H. Siebert
R. A. Shaw
J. Ditas
T. Schmeissner
S. P. Malinowski
E. Bodenschatz
H. Xu
High-resolution measurement of cloud microphysics and turbulence at a mountaintop station
Atmospheric Measurement Techniques
author_facet H. Siebert
R. A. Shaw
J. Ditas
T. Schmeissner
S. P. Malinowski
E. Bodenschatz
H. Xu
author_sort H. Siebert
title High-resolution measurement of cloud microphysics and turbulence at a mountaintop station
title_short High-resolution measurement of cloud microphysics and turbulence at a mountaintop station
title_full High-resolution measurement of cloud microphysics and turbulence at a mountaintop station
title_fullStr High-resolution measurement of cloud microphysics and turbulence at a mountaintop station
title_full_unstemmed High-resolution measurement of cloud microphysics and turbulence at a mountaintop station
title_sort high-resolution measurement of cloud microphysics and turbulence at a mountaintop station
publisher Copernicus Publications
series Atmospheric Measurement Techniques
issn 1867-1381
1867-8548
publishDate 2015-08-01
description Mountain research stations are advantageous not only for long-term sampling of cloud properties but also for measurements that are prohibitively difficult to perform on airborne platforms due to the large true air speed or adverse factors such as weight and complexity of the equipment necessary. Some cloud–turbulence measurements, especially Lagrangian in nature, fall into this category. We report results from simultaneous, high-resolution and collocated measurements of cloud microphysical and turbulence properties during several warm cloud events at the Umweltforschungsstation Schneefernerhaus (UFS) on Zugspitze in the German Alps. The data gathered were found to be representative of observations made with similar instrumentation in free clouds. The observed turbulence shared all features known for high-Reynolds-number flows: it exhibited approximately Gaussian fluctuations for all three velocity components, a clearly defined inertial subrange following Kolmogorov scaling (power spectrum, and second- and third-order Eulerian structure functions), and highly intermittent velocity gradients, as well as approximately lognormal kinetic energy dissipation rates. The clouds were observed to have liquid water contents on the order of 1 g m<sup>−3</sup> and size distributions typical of continental clouds, sometimes exhibiting long positive tails indicative of large drop production through turbulent mixing or coalescence growth. Dimensionless parameters relevant to cloud–turbulence interactions, the Stokes number and settling parameter are in the range typically observed in atmospheric clouds. Observed fluctuations in droplet number concentration and diameter suggest a preference for inhomogeneous mixing. Finally, enhanced variance in liquid water content fluctuations is observed at high frequencies, and the scale break occurs at a value consistent with the independently estimated phase relaxation time from microphysical measurements.
url http://www.atmos-meas-tech.net/8/3219/2015/amt-8-3219-2015.pdf
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