Abstract
Gridded passive microwave brightness temperatures (TB) from special sensor microwave imager and sounder (SSMIS) instruments on three different satellite platforms are compared in different years to investigate the consistency between the sensors over time. The orbits of the three platforms have drifted over their years of operation, resulting in changing relative observing times that could cause biases in TB estimates and near-real-time sea ice concentrations derived from the NASA Team algorithm that are produced at the National Snow and Ice Data Center. Comparisons of TB histograms and concentrations show that there are small mean differences between sensors, but variability within an individual sensor is much greater. There are some indications of small changes due to orbital drift, but these are not consistent across different frequencies. Further, the overall effect of the drift, while not definitive, is small compared to the intra- and interannual variability in individual sensors. These results suggest that, for near-real-time use, the differences in the sensors are not critical. However, for long-term time series, even the small biases should be corrected for. The strong day-to-day, seasonal, and interannual variability in TB distributions indicate that time-varying algorithm coefficients in the NASA team algorithm would lead to improved, more consistent sea ice concentration estimates.
Highlights
Sea ice concentrations from passive microwave sensors provide one of the longest satellite-derived climate records
Passive microwave (PM) sensors are useful for observing sea ice because, at the frequencies used for the retrievals, atmospheric emissions are generally small and surface emission is not dependent on solar illumination
From 2009 until 2016, F17 was used for public distribution, but NSIDC switched to F18 for NRT TBs and sea ice concentrations in March 2016 after issues arose with the sensor microwave imager and sounder (SSMIS) sensor on F17
Summary
Sea ice concentrations from passive microwave sensors provide one of the longest satellite-derived climate records. In the Arctic, these fields are key indicators of climate change, showing a significant decline in sea ice extent, during summer, e.g., [1]. In the Antarctic, trends are near zero and exhibit strong interannual variability, e.g., [2]. These sea ice trends are indicative of large-scale climate change within the polar climate system, e.g., [3]. Satellite-borne multi-channel passive microwave sensors have been in near-continuous operation since 1978, beginning with the launch of the NASA scanning multichannel microwave radiometer (SMMR) on the Nimbus-7 platform. Beginning in July 1987, a series of special sensor microwave imager (SSMI) and special sensor microwave imager and sounder (SSMIS) sensors have been launched on
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