Abstract
Backscattering coefficients of Sentinel-1 synthetic aperture radar (SAR) data of drifting multi-year sea ice in the western Beaufort Sea during the transition period between the end of melting and onset of freeze-up are analyzed, in terms of the incidence angle dependence and temporal variation. The mobile sea ice surface is tracked down in a 1 km by 1 km region centered at a GPS tracker, which was installed during a field campaign in August 2019. A total of 24 Sentinel-1 images spanning 17 days are used and the incidence angle dependence in HH- and HV-polarization are −0.24 dB/deg and −0.10 dB/deg, respectively. Hummocks and recently frozen melt ponds seem to cause the mixture behavior of surface and volume scattering. The normalized backscattering coefficients in HH polarization gradually increased in time at a rate of 0.15 dB/day, whereas the HV-polarization was relatively flat. The air temperature from the ERA5 hourly reanalysis data has a strong negative relation with the increasing trend of the normalized backscattering coefficients in HH-polarization. The result of this study is expected to complement other previous studies which focused on winter or summer seasons in other regions of the Arctic Ocean.
Highlights
The Arctic Sea ice cover plays an important role in mediating the global climate through the ice-albedo feedback mechanism [1]
This study focuses on a large sea ice floe in the marginal ice zone of the western Beaufort Sea, north of Alaska, where a field campaign was carried on from August 12 to 15 in 2019 by ice breaker research
This study focuses on a large sea ice floe in the marginal ice zone of the western Beaufort Sea, vessenlo(IrBthRoVf)AAlarsakoan, w(Fhiegrueraef1ieal)d
Summary
The Arctic Sea ice cover plays an important role in mediating the global climate through the ice-albedo feedback mechanism [1]. The Arctic climate has been shifting rapidly and sea ice extent and thickness have substantially declined with more and more extreme cases [2,3,4,5]. As sea ice extent and thickness decreases, thick multi-year sea ice (MYI) has been replaced by thinner first-year sea ice (FYI) [5,9]. Synthetic aperture radar (SAR) for the most part has been an efficient tool in several sea ice applications, owing to its all-weather and 24-hour high-resolution data which can distinguish between sea ice, snow, and open water [10,11,12,13]. Longer wavelength SAR sensors with multiple polarizations have been proven to effectively distinguish between FYI and MYI as the backscatter contrast is high [14,15,16,17]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
