Changing Arctic snow cover: a review of recent developments and assessment of future needs for observations, modelling and impacts. Ambio. 45, 516-537.(2016).
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.(2013).
Weekly-gridded Aquarius L-band radiometer/scatterometer observations and salinity retrievals over the polar regions, part 1: Product description. The Cryosphere. 8, 905-913.(2014).
Snow grain size profile deduced from microwave snow emissivities in Antarctica. Journal of Glaciology. 56(197), 514-524.(2010).
Modeling time series of microwave brightness temperature at Dome C, Antarctica, using vertically resolved snow temperature and microstructure measurements. Journal of Glaciology. 57(201), 171-182.(2011).
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).
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).
Current Climate Trends in the Arctic. WIREs Climate Change, Wiley Interdisciplinary Reviews (WIREs).(2014).
Multitemporal snow cover mapping in mountainous terrain for Landsat climate data record development. Remote Sensing of Environment. 135, 224-233.(2013).
Development of a rain-on-snow detection algorithm using passive microwave radiometry. Hydrological Processes. 30, 3184-3196.(2016).
A First Assessment of IceBridge Snow and Ice Thickness Data over Arctic Sea Ice. Trans. Geosc. Rem. Sens.. 50(6),(2012).
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).
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).
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).
Ground thermal profiles from Mount Kenya, East Africa. Geografiska Annaler (Series A). 86 (2), 131-141.(2004).
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).
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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).