Abstract
Monitoring melt extent and timing on the Greenland ice sheet is important for tracking the ice sheet's mass and energy balance as well as the global and Arctic climate variability and change. In this study, we use L -band (1.4 GHz) brightness temperature observations collected by NASA's soil moisture active passive (SMAP) mission to investigate the extent, duration, and intensity of melt events on the Greenland ice sheet from 2015 to 2021. SMAP provides nearly all-weather surface monitoring over all of Greenland twice daily with morning and evening overpasses at approximately 40-km spatial resolution. We applied empirical threshold and geophysical-model-based algorithms using horizontally and vertically polarized microwave brightness temperature differences to quantify both the intensity and extent of surface melting. Analysis of the melt seasons shows that Greenland experienced unusually strong melt events at the end of July 2019 and on August 14, 2021, which extended the melt area across much of the dry snow zone over a period of one and two days, respectively. In situ temperatures measured at Greenland's Summit station confirm the above freezing temperatures during these extreme events.
Highlights
About 8% of the world’s ice is located on the Greenland ice sheet
We investigated the response of the Lband radiometer on the NASA SMAP (Soil Moisture Active Passive) satellite, launched in January 2015, to the Greenland ice sheet’s melt events [11]
Ice Sheet (PROMICE), used in this study is derived from analysis of an aero-photogrammetric map of Greenland acquired in the 1980s [22]
Summary
About 8% of the world’s ice is located on the Greenland ice sheet. The melting of this large ice mass over land due to global warming is estimated to contribute approximately 0.72 mm/yr to global sea level rise [1, 2, 3]. Houtz et al [13] quantified surface melt on the Greenland ice sheet using microwave brightness temperature measured at 1.4 GHz by the European Space Agency (ESA) Soil Moisture and Ocean Salinity (SMOS) from 2011 to 2018. They used the Microwave Emission Model of Layered Snowpacks (MEMLS) [14] with a different layer configuration from our model. The similarities and differences during the overlapped period of investigation (2015-2018) between the results obtained with the model used here and [13] are discussed in different sections of this paper
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