Abstract

Synthetic Aperture Radar (SAR) data has become an important tool for studies of polar regions, due to high spatial resolution even during the polar night and under cloudy skies. We have studied the temporal variation of sea and land ice backscatter of twenty‐four SAR images from the European Remote Sensing satellite (ERS‐1) covering an area in Lady Ann Strait and Jones Sound, Nunavut, from January to March 1992. The presence of fast ice in Jones Sound and glaciers and ice caps on the surrounding islands provides an ideal setting for temporal backscatter studies of ice surfaces. Sample regions for eight different ice types were selected and the temporal backscatter variation was studied. The observed backscatter values for each ice type characterize the radar signatures of the ice surfaces. This time series of twenty‐four SAR images over a 3‐month period provides new insights into the degree of temporal variability of each surface. Ice caps exhibit the highest backscatter value of ‐3.9 dB with high temporal variability. Valley glacier ice backscatter values decrease with decreasing altitude, and are temporally the most stable, with standard deviations of 0.08–0.10 dB over the 90‐day period. First‐year ice and lead ice show a negative trend in backscatter values in time and a positive correlation of up to 0.59 with air temperature over the 90‐day period. For first‐year ice and lead ice, episodes of large temperature fluctuations (±12°C) are associated with rapid changes in backscatter values (±2 dB). We attribute the backscatter increase to a temperature‐induced increase in brine volume at the base of the snow pack. Multi‐year ice, conglomerate ice and shore ice are relatively stable over the 3‐month period, with a backscatter variation of only a few dBs. An observed lag time of up to three days between backscatter increase/decrease and air temperature can be attributed to the insulation effect of the snow cover over sea ice. The net range of the backscatter values observed on the most temporally stable surface, valley glacier ice, of about 0.30 dB indicates that the ERS‐1 SAR instrument exceeds the 1 dB calibration accuracy specified for the Alaska SAR Facility processor for the three winter months.

Highlights

  • Monitoring sea ice in polar regions is essential for the understanding of climate processes

  • We have studied the temporal variation of sea and land ice backscatter of twenty-four Synthetic Aperture Radar (SAR) images from the European Remote Sensing satellite (ERS-1) covering an area in Lady Ann Strait and Jones Sound, Nunavut, from January to March 1992

  • In this paper we examine the temporal variations of SAR backscatter for several types of sea and land ice with the intent of better understanding the processes at that interface

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Summary

Introduction

Monitoring sea ice in polar regions is essential for the understanding of climate processes. In this paper we examine the temporal variations of SAR backscatter for several types of sea and land ice with the intent of better understanding the processes at that interface. The European Remote Sensing satellite (ERS-1), because of its 3-day repeat orbit ( called the ice cycle) during the months of January to March 1992, has the necessary temporal resolution required to study the evolution of the ice cover and its dynamic change due to weather or ocean currents. We analyze twenty-four Synthetic Aperture Radar (SAR) images for the backscatter variability of different ice types over a 3-month period and relate those changes to variations in air temperature recorded at the nearby Grise Fiord meteorological station on Ellesmere Island. SAR data are a useful tool in high latitude regions because data quality is maintained even in cloudy conditions and at night

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