The microwave snow grain size: a new concept to predict satellite observations over snow-covered regions

This is a Preprint and has not been peer reviewed. The published version of this Preprint is available: https://doi.org/10.1029/2021AV000630. This is version 1 of this Preprint.

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Authors

Ghislain Picard, Henning Löwe, Florent Domine, Laurent Arnaud, Fanny Larue, Vincent Favier, Emmanuel Le Meur, Eric Lefebvre, Joel Savarino, Alain Royer

Abstract

Satellite observations of snow-covered regions in the microwave range have the potential to retrieve essential climate variables such as snow height. This requires a precise understanding of how microwave scattering is linked to snow microstructural properties (density, grain size, grain shape and arrangement). This link has so far relied on empirical adjustments of the theories, precluding the development of robust retrieval algorithms. Here we solve this problem by introducing a new microstructural parameter able to consistently predict scattering. This “microwave grain size” is demonstrated to be proportional to the measurable optical grain size and to a new factor describing the chord length dispersion in the microstructure, a geometrical property known as polydispersity. By assuming that the polydispersity depends on the snow grain type only, we retrieve its value for rounded and faceted grains by optimization of microwave satellite observations in 18 Antarctic sites, and for depth hoar in 86 Canadian sites using ground-based observations. The value for the convex grains (0.6) compares favorably to the polydispersity calculated from 3D micro-computed tomography images for alpine grains, while values for depth hoar show wider variations (1.2–1.9) and are larger in Canada than in the Alps. Nevertheless, using one value for each grain type, the microwave observations in Antarctica and in Canada can be simulated from in-situ measurements with good accuracy with a fully physical model. These findings improve snow scattering modeling, enabling future more accurate uses of satellite observations in snow hydrological and meteorological applications.

DOI

https://doi.org/10.31223/X5KK9Z

Subjects

Physical Sciences and Mathematics

Keywords

Microwave, scattering, snow, Antarctica, Canada, remote sensing

Dates

Published: 2022-05-20 04:40

License

CC BY Attribution 4.0 International

Additional Metadata

Conflict of interest statement:
The authors declare no conflicts of interest relevant to this study.

Data Availability (Reason not available):
data are available