New methods for detecting dynamic and thermodynamic characteristics of sea ice from radar remote sensing

This dissertation presents new methods for detecting dynamic and thermodynamic characteristics of Arctic sea ice using radar remote sensing. A new technique for sea ice motion detection from sequential satellite synthetic aperture radar (SAR) images was developed and thoroughly validated. The accura...

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Bibliographic Details
Main Author: Komarov, Alexander
Other Authors: Shafai, Lotfollah (Electrical and Computer Engineering) Barber, David (Environment and Geography), Mojabi, Puyan (Electrical and Computer Engineering) Ehn, Jens (Environment and Geography) Dierking, Wolfgang (Alfred Wegener Institute for Polar and Marine Research)
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: Institute of Electrical and Electronics Engineers 2014
Subjects:
Arctic sea ice
synthetic aperture radar
sea ice motion
ocean surface wind speed
electromagnetic wave scattering
modeling
snow on sea ice
Arctic
Beaufort Sea
Sea ice
Online Access:http://hdl.handle.net/1993/30225
Description
Summary:This dissertation presents new methods for detecting dynamic and thermodynamic characteristics of Arctic sea ice using radar remote sensing. A new technique for sea ice motion detection from sequential satellite synthetic aperture radar (SAR) images was developed and thoroughly validated. The accuracy of the system is 0.43 km obtained from a comparison between SAR-derived ice motion vectors and in-situ sea ice beacon trajectories. For the first time, we evaluated ice motion tracking results derived from co-polarization (HH) and cross-polarization (HV) channels of RADARSAT-2 ScanSAR imagery and formulated a condition where the HV channel is more reliable than the HH channel for ice motion tracking. Sea ice motion is substantially controlled by surface winds. Two new models for ocean surface wind speed retrieval from C-band SAR data have been developed and validated based on a large body of statistics on buoy observations collocated and coincided with RADARSAT-1 and -2 ScanSAR images. The proposed models without wind direction input demonstrated a better accuracy than conventionally used algorithms. As a combination of the developed methods we designed a wind speed-ice motion product which can be a useful tool for studying sea ice dynamics processes in the marginal ice zone. To effectively asses the thermodynamic properties of sea ice advanced tools for modeling electromagnetic (EM) wave scattering from rough natural surfaces are required. In this dissertation we present a new analytical formulation for EM wave scattering from rough boundaries interfacing inhomogeneous media based on the first-order approximation of the small perturbation method. Available solutions in the literature represent special cases of our general solution. The developed scattering theory was applied to experimental data collected at three stations (with different snow thicknesses) in the Beaufort Sea from the research icebreaker Amundsen during the Circumpolar Flaw Lead system study. Good agreement between the model and experimental data ...

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