Ku-, X- and C-band measured and modeled microwave backscatter from a highly saline snow cover on first-year sea ice

Ku-, X- and C-band measured and modeled microwave backscatter from a highly saline snow cover on first-year sea ice

In this study, we inter-compare observed and modeled Ku-, X- and C-band microwave backscatter for two snow temperature conditions for a highly saline snow cover on smooth first-year sea ice. A new surface-based multi-frequency (Ku-, X- and C-bands) microwave scatterometer system is used quasi-coinci...

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Bibliographic Details
Published in:Remote sensing of environment Vol. 187; pp. 62 - 75
Main Authors: Nandan, Vishnu, Geldsetzer, Torsten, Islam, Tanvir, Yackel, John. J., Gill, Jagvijay P.S., Fuller, Mark. C., Gunn, Grant, Duguay, Claude
Format: Journal Article
Language:English
Published: Elsevier Inc 01-12-2016
Subjects:
Active microwaves
Backscattering
Geophysics
Marine
Mathematical models
Microwave scattering
Microwaves
Saline
Sea ice
Snow
Snow cover
Microwave scattering
Snow
Active microwaves
Sea ice
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Summary:In this study, we inter-compare observed and modeled Ku-, X- and C-band microwave backscatter for two snow temperature conditions for a highly saline snow cover on smooth first-year sea ice. A new surface-based multi-frequency (Ku-, X- and C-bands) microwave scatterometer system is used quasi-coincident with in situ geophysical snow measurements. A multilayer snow and ice backscatter model is used to calculate the total co-polarized backscatter coefficient for two snow temperature conditions. The model provides the surface and volume scattering contributions for each snow layer, as well as the frequency-dependent penetration depth. These results aid interpretation of observed backscatter. Joint use of Ku-, X- and C-band microwaves provide an enhanced understanding of diverse variations in geophysical, thermodynamic and electrical state of snow/sea ice system. Our results indicate that the effect of dielectric loss associated with highly saline snow covers is the dominant factor affecting microwave penetration and backscatter from all three frequencies. The observed and modeled C-band backscatter shows good agreement, followed by X- and Ku-bands, at both snow temperature conditions. Microwave backscatter shows greater sensitivity to variations in plot-scale surface roughness, for all three frequencies. Additionally, Ku-band wavelength exhibits greater sensitivity to snow grain radius, over X-, and C-bands. Our results demonstrate the future potential of a multi-frequency approach towards the development of snow thickness and snow water equivalent algorithms on first-year sea ice. •Unique Ku-, X- and C-band microwave scatterometer system for snow covered sea ice.•Ku-, X- and C-band microwaves fluctuated at varying snow temperature conditions.•High snow salinity strongly attenuates Ku-, X- and C-band microwave propagation.•Snow surface/interface roughness changes affect X-band microwave backscatter.•High frequency Ku-band microwaves show greater sensitivity to snow grain size.
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ISSN:0034-4257
1879-0704
DOI:10.1016/j.rse.2016.10.004