Tobin, CaraSchaefli, BettinaNicotina, LudovicoSimoni, SilviaBarrenetxea, GuillermoSmith, RusselParlange, MarcRinaldo, Andrea2013-05-022013-05-022013-05-02201310.1016/j.advwatres.2012.08.008https://infoscience.epfl.ch/handle/20.500.14299/91924WOS:000318605000014This paper proposes a new extension of the classical degree-day snowmelt model applicable to hourly simulations for regions with limited data and adaptable to a broad range of spatially-explicit hydrological models. The snowmelt schemes have been tested with a point measurement dataset at the Cotton Creek Experimental Watershed (CCEW) in British Columbia, Canada and with a detailed dataset available from the Dranse de Ferret catchment, an extensive ly monitor ed catchment in the Swiss Alps. The snowmelt model performance is quantified with the use of a spatially-explicit model of the hydrologic response. Comparative analyses are presented with the widely-known, grid-based method proposed by Hock which combines a local, temperature-index approach with potential radiation. The results suggest that a simple diurnal cycle of the degree-day melt parameter based on minimum and maximum temperature s is competitive with the Hock approach for sub-daily melt simulations. Advantages of the new extension of the classical degree-da y method over other temperature-index methods include its use of physically-based, diurnal variations and its abil ity to be adapted to data-constrained hydrological models which are lumped in some nature.Snowmelt comparisonTemperature index methodsSpatially-explicit hydrological modelingWireless meteorological networktext::journal::journal article::research article