The Estimation of the Total Freeboard of Arctic Sea Ice in Winter Using Passive Microwave Satellite Measurements

Abstract A method for estimating the total freeboard h f of the sea ice in the Arctic basin was developed in this study. To utilize the dielectric properties of microwave measurements on the sea ice freeboard, we adopted the spectral difference between the microwave frequencies (e.g., the gradient r...

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Published inJournal of atmospheric and oceanic technology Vol. 39; no. 10; pp. 1611 - 1627
Main Authors Kim, Jong-Min, Sohn, Byung-Ju, Lee, Sang-Moo, Shi, Hoyeon, Kwon, Young-Joo, Kim, Sang-Woo, Kim, Hyun-Cheol
Format Journal Article
LanguageEnglish
Published Boston American Meteorological Society 01.10.2022
Subjects
Airborne sensing
Altimeters
Altimetry
Arctic sea ice
Brightness temperature
Climate change
Climate change monitoring
Climate monitoring
Correlation coefficient
Correlation coefficients
Dielectric properties
Electrical properties
Estimation
Freeboard
Geographical distribution
Hydrostatic equation
Ice
Ice cover
Ice thickness
Lidar
Long-term records
Methods
Microwave frequencies
Microwave sensors
Radar
Radiometry
Salinity
Satellite data
Satellite observation
Satellites
Sea ice
Sea ice thickness
Snow
Surface radiation temperature
Thickness
Variables
Winter
Arctic region
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Summary:Abstract A method for estimating the total freeboard h f of the sea ice in the Arctic basin was developed in this study. To utilize the dielectric properties of microwave measurements on the sea ice freeboard, we adopted the spectral difference between the microwave frequencies (e.g., the gradient ratio). Satellite lidar altimetry data were utilized as a reference, and two pairs of gradient ratios [GR(36.5, 18.7) and GR(10.7, 6.9)] and an optional brightness temperature for first-year ice [that is, TB H (6.9)] were converted from passive microwave sensors into h f using the multiple linear regression equation. Using this method, we estimated h f without direct altimetry measurements. The developed method was evaluated using Operation IceBridge data and the relationship between the regressed h f and Operation IceBridge h f had a correlation coefficient R of 0.761 and a nearly unbiased (approximately −0.4 cm) pattern. Because passive microwave measurements are taken in the Arctic daily, the approach presented in this study has the potential to enable daily h f estimations for the Arctic. Significance Statement Arctic sea ice is one of the most critical indicators when monitoring climate change. Precise and continuous observations of sea ice thickness are essential to understand Arctic sea ice. This study attempts to estimate sea ice thickness using passive microwave satellite data. Passive microwave satellite observations are advantageous because of their wide spatial coverage and long-term records. Therefore, the suggested method in this study can be used for filling in gaps in coverage between sea ice thickness estimates from L-band radiometry and radar/lidar altimetry. The total freeboard is proportional to the thickness of sea ice, which is converted into thickness using the hydrostatic equation. The estimated total freeboard during two winter periods (2018/19 and 2019/20) demonstrates a plausible geographical distribution over the Arctic and indicates good agreement with airborne measurements.
ISSN:0739-0572
1520-0426
DOI:10.1175/JTECH-D-21-0105.1