Publications

Hall, DK; O'Leary, DS; DiGirolamo, NE; Miller, W; Kang, DH (2021). The role of declining snow cover in the desiccation of the Great Salt Lake, Utah, using MODIS data. REMOTE SENSING OF ENVIRONMENT, 252, 112106.

Abstract
The Great Salt Lake (GSL) in Utah has been shrinking since the middle of the 19th Century, leading to decreased area and volume, and increased salinity. We use satellite data products from the Terra and Aqua MODerateresolution Imaging Spectroradiometer (MODIS) and the Landsat-7 and-8 satellites, along with meteorological and streamflow data, and modeled data products to study the relationship between changing snow-cover conditions and the decline of the GSL since 2000 in the context of the historical record of lake levels. The GSL basin includes much of the snow-dominated Wasatch and Uinta mountain ranges to the east of the lake. Snowmelt feeds the Bear, Jordan, and Weber rivers which are the three main rivers that flow into the lake. Snowmelttiming maps, derived from a new MODIS standard snow-cover product, MOD10A1F, show that snow melted-9.5 days earlier in the GSL basin during the study period, extending from 2000 to 2018. Air temperatures derived from 26 meteorological stations and surface temperatures measured by the Aqua MODIS land-surface temperature (LST) products, MYD21A1D and MYD21A1N, show trends of increasing temperature of similar to 0.94 degrees C (alpha = 0.05), and similar to 2.18 degrees C, respectively, with most of the LST trends in the GSL basin being statistically significant (alpha = 0.05). Increasing air temperatures in the basin have led to less precipitation falling as snow, lower snow depth (by-34.5 mm (alpha = 0.01)) and snow-water equivalent (0.02 mm (alpha = 0.01)), and earlier snowmelt. Also during the study period, Global Land surface Evaporation Amsterdam Model data show evaporation increasing by similar to 3.2 mm/yr, with trends in much of the basin being statistically significant (alpha = 0.05). Trends calculated from the various products are generally in agreement indicating higher temperatures, greater evaporation, less snowfall and snow-on-the ground, and earlier snowmelt. Earlier snowmelt contributes to increasing evaporative loss from water flowing toward the lake. Furthermore, a lower mountain snowpack and less precipitation falling as snow (versus rain) is associated with lower stream discharge even if overall precipitation stays the same. The surface-water temperature of the GSL also increased over the study period by similar to 0.69 degrees C, according to the MODIS LST data products, the surface-water elevation of the lake dropped by similar to 1.7 m between 2000 and 2018, and the areal extent of the lake decreased by similar to 901 km(2) as measured using Landsat imagery. Desiccation of the lake is associated with deleterious effects on wildlife, recreational activities, and some local industries. And, importantly, an expanding lake bed can also fuel dust storms that promote dangerous air quality along the Wasatch Front. This work elucidates the key role that satellite remote sensing can play in documenting earlier snowmelt and other changes in the GSL basin that influence the ongoing decline of the Great Salt Lake.

DOI:
10.1016/j.rse.2020.112106

ISSN:
0034-4257