
Further Reading
The microwave properties of simulated melting precipitation particles: sensitivity to initial melting.
Atmos. Meas. Tech. 9, 9-21.
(2016). Variability in the surface temperature and melt extent of the Greenland ice sheet from MODIS.
Geophysical Research Letters. 40, 1-7.
(2013). Uncertainties of temperature measurements on snow-covered land and sea ice from in-situ and MODIS data during BROMEX.
Journal of Applied Meteorology and Climatology. 54(5), 966-978.
(2015). Development and validation of a cloud-gap filled MODIS daily snow-cover product.
Remote Sensing of Environment. 114, 496-503.
(2010). A multilayer IST – albedo product of Greenland from MODIS.
Remote Sensing [Special Issue: Remote Sensing of Essential Climate Variables and their Applications]. 10(4), 555.
(2018). Detection of earlier snowmelt in the Wind River Range, Wyoming, using Landsat imagery.
Remote Sensing of Environment. 162, 45-54.
(2015). On the frequency of lake-effect snowfall in the Catskill Mountains.
Physical Geography. 1-17.
(2018). Global Snow Cover.
Satellite Image Atlas of Glaciers (Williams, R.S., Jr. and J.G. Ferrigno, eds.) USGS Professional Paper 1386-A..
(2012). Accuracy assessment of the MODIS snow-cover products.
Hydrological Processes.
(2007). Comparison of satellite-derived ice and snow surface temperatures over Greenland from MODIS, ASTER, ETM+ and in-situ observations.
Remote Sensing of Environment. 112(10), 3739-3749.
(2008). A Satellite-Derived Climate-Quality Data Record of the Clear-Sky Surface Temperature of the Greenland Ice Sheet.
Journal of Climate. 25(14), 4785-4798.
(2012). Ground thermal profiles from Mount Kenya, East Africa.
Geografiska Annaler (Series A). 86 (2), 131-141.
(2004). Airborne spectral BRDF of various surface types (ocean, vegetation, snow, desert, wetlands, cloud decks, smoke layers) for remote sensing applications.
Remote Sensing of Environment. 179, 131-148.
(2016). Seasonal Snow Extent and Snow Mass in South America Using SMMR and SSM/I Passive Microwave Data (1979-2003).
Remote Sensing of Environment. 113, 291-305.
(2009). Passive Microwave Remote Sensing of the Historic February 2010 Snow Storms in the Middle Atlantic Region of the U.S..
Hydrol. Processes. 26(22), 3459-3471.
(2012). A First Assessment of IceBridge Snow and Ice Thickness Data over Arctic Sea Ice.
Trans. Geosc. Rem. Sens.. 50(6),
(2012). Development of a rain-on-snow detection algorithm using passive microwave radiometry.
Hydrological Processes. 30, 3184-3196.
(2016). Multitemporal snow cover mapping in mountainous terrain for Landsat climate data record development.
Remote Sensing of Environment. 135, 224-233.
(2013). Current Climate Trends in the Arctic.
WIREs Climate Change, Wiley Interdisciplinary Reviews (WIREs).
(2014). A comparison of snow depth on sea ice retrievals using airborne atlimeters and an AMSR-E simulator..
IEEE Transactions on Geoscience & Remote Sensing. 50(8), 3027-3040.
(2012). Hourly simulations of the microwave brightness temperature of seasonal snow in Quebec, Canada, using a coupled snow evolution-emission model.
Remote Sensing of Environment. 115(8), 1966-1977.
(2011). Effect of snow surface metamorphism on Aquarius L-band radiometer observations at Dome C, Antarctica.
IEEE Transactions on Geoscience & Remote Sensing. 52(11), 7408-7417.
(2014). Weekly-gridded Aquarius L-band radiometer/scatterometer observations and salinity retrievals over the polar regions, part 2: Initial product analysis.
The Cryosphere. 8, 915-930.
(2014). Arctic-scale assessment of satellite passive microwave-derived snow depth on sea ice using Operation IceBridge airborne data.
J. Geophys. Res. Oceans. 118(6), 2892-2905.
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