Affiliation:
1. Climate Impacts Group, JISAO/SMA CSES, and Department of Civil and Environmental Engineering, University of Washington, Seattle, Washington
2. Department of Civil and Environmental Engineering, and Climate Impacts Group, JISAO/SMA CSES, University of Washington, Seattle, Washington
Abstract
Abstract
The availability of long-term gridded datasets of precipitation, temperature, and other surface meteorological variables offers the potential for deriving a range of land surface conditions that have not been directly observed. These include, for instance, soil moisture, snow water equivalent, evapotranspiration, runoff, and subsurface moisture transport. However, gridding procedures can themselves introduce artificial trends due to incorporation of stations with different record lengths and locations. Hence, existing gridded datasets are in general not appropriate for estimation of long-term trends. Methods are described here for adjustment of gridded daily precipitation and temperature maxima and minima over the continental United States based on newly available (in electronic form) U.S. Cooperative Observer station data archived at the National Climatic Data Center from the early 1900s on. The intent is to produce gridded meteorological datasets that can be used, in conjunction with hydrologic modeling, for long-term trend analysis of simulated hydrologic variables.
Publisher
American Meteorological Society
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