Abstract
ABSTRACTChanging Arctic sea-ice extent and melt season duration, and increasing economic interest in the Arctic have prompted the need for enhanced marine ecosystem studies and improvements to dynamical and forecast models. Sea-ice melt pond fraction fp has been shown to be correlated with the September minimum ice extent due to its impact on ice albedo and heat uptake. Ice forecasts should benefit from knowledge of fp as melt ponds form several months in advance of ice retreat. This study goes further back by examining the potential to predict fp during winter using backscatter data from the commonly available Sentinel-1 synthetic aperture radar. An object-based image analysis links the winter and spring thermodynamic states of first-year and multiyear sea-ice types. Strong correlations between winter backscatter and spring fp, detected from high-resolution visible to near infrared imagery, are observed, and models for the retrieval of fp from Sentinel-1 data are provided (r2 ≥ 0.72). The models utilize HH polarization channel backscatter that is routinely acquired over the Arctic from the two-satellite Sentinel-1 constellation mission, as well as other past, current and future SAR missions operating in the same C-band frequency. Predicted fp is generally representative of major ice types first-year ice and multiyear ice during the stage in seasonal melt pond evolution where fp is closely related to spatial variations in ice topography.
Highlights
Recent changes in Arctic sea-ice conditions are well documented
As a key first step to the development of a melt pond fraction prediction model, we examined the roles of incidence angle and scale on correlations between backscatter parameters and pond fraction
Backscatter parameters σh° h and σh° v, and grey-level co-occurrence matrix (GLCM) texture parameters derived from σh° h and σh° v, and spring melt pond fraction on all ice types are strongly correlated
Summary
Recent changes in Arctic sea-ice conditions are well documented. There is a new Arctic sea-ice regime, characterized over the last 35 years by a rapidly declining summer ice extent and, since 2007, a shift from predominantly thicker multiyear sea ice (MYI) to thinner, seasonally decaying, first-year sea ice (FYI) (Giles and others, 2008; Kwok and others, 2009; Kwok and Rothrock, 2009; Laxon and others, 2013). Backscatter and GLCM texture parameters derived from the HH polarization channel were used, and input data from only one site were used in order to control for temporal fluctuations in pond fraction (see Melt pond prediction model section).
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