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1. Observations and simulations of the seasonal evolution of snowpack cold content and its relation to snowmelt and the snowpack energy budget

   https://doi.org/10.5194/tc-12-1595-2018  

   Jennings, Keith S. ; Kittel, Timothy G. ; Molotch, Noah P. ( January 2018 , The Cryosphere)

   Abstract. Cold content is a measure of a snowpack's energy deficit and is a linear function of snowpack mass and temperature. Positive energy fluxes into a snowpack must first satisfy the remaining energy deficit before snowmelt runoff begins, making cold content a key component of the snowpack energy budget. Nevertheless, uncertainty surrounds cold content development and its relationship to snowmelt, likely because of a lack of direct observations. This work clarifies the controls exerted by air temperature, precipitation, and negative energy fluxes on cold content development and quantifies the relationship between cold content and snowmelt timing and rate at daily to seasonal timescales. The analysis presented herein leverages a unique long-term snow pit record along with validated output from the SNOWPACK model forced with 23 water years (1991–2013) of quality controlled, infilled hourly meteorological data from an alpine and subalpine site in the Colorado Rocky Mountains. The results indicated that precipitation exerted the primary control on cold content development at our two sites with snowfall responsible for 84.4 and 73.0% of simulated daily gains in the alpine and subalpine, respectively. A negative surface energy balance – primarily driven by sublimation and longwave radiation emission from the snowpack – during days without snowfall provided a secondary pathway for cold content development, and was responsible for the remaining 15.6 and 27.0% of cold content additions. Non-zero cold content values were associated with reduced snowmelt rates and delayed snowmelt onset at daily to sub-seasonal timescales, while peak cold content magnitude had no significant relationship to seasonal snowmelt timing. These results suggest that the information provided by cold content observations and/or simulations is most relevant to snowmelt processes at shorter timescales, and may help water resource managers to better predict melt onset and rate.

    

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2. Roots Mediate the Effects of Snowpack Decline on Soil Bacteria, Fungi, and Nitrogen Cycling in a Northern Hardwood Forest

   https://doi.org/10.3389/fmicb.2019.00926  

   Sorensen, Patrick O. ; Bhatnagar, Jennifer M. ; Christenson, Lynn ; Duran, Jorge ; Fahey, Timothy ; Fisk, Melany C. ; Finzi, Adrien C. ; Groffman, Peter M. ; Morse, Jennifer L. ; Templer, Pamela H. ( April 2019 , Frontiers in Microbiology)
3. Impact of Initialized Land Surface Temperature and Snowpack on Subseasonal to Seasonal Prediction Project, Phase I (LS4P-I): organization and experimental design

   https://doi.org/10.5194/gmd-14-4465-2021  

   Xue, Yongkang ; Yao, Tandong ; Boone, Aaron A. ; Diallo, Ismaila ; Liu, Ye ; Zeng, Xubin ; Lau, William K. ; Sugimoto, Shiori ; Tang, Qi ; Pan, Xiaoduo ; et al ( January 2021 , Geoscientific Model Development)

   Abstract. Subseasonal-to-seasonal (S2S) prediction, especially the prediction of extreme hydroclimate events such as droughts and floods, is not only scientifically challenging, but also has substantial societal impacts. Motivated by preliminary studies, the Global Energy and Water Exchanges(GEWEX)/Global Atmospheric System Study (GASS) has launched a new initiativecalled “Impact of Initialized Land Surface Temperature and Snowpack on Subseasonal to Seasonal Prediction” (LS4P) as the first international grass-roots effort to introduce spring land surface temperature(LST)/subsurface temperature (SUBT) anomalies over high mountain areas as acrucial factor that can lead to significant improvement in precipitationprediction through the remote effects of land–atmosphere interactions. LS4P focuses on process understanding and predictability, and hence it is differentfrom, and complements, other international projects that focus on theoperational S2S prediction. More than 40 groups worldwide have participated in this effort, including 21 Earth system models, 9 regionalclimate models, and 7 data groups. This paper provides an overview of the history and objectives of LS4P, provides the first-phase experimental protocol (LS4P-I) which focuses on the remote effect ofthe Tibetan Plateau, discusses the LST/SUBT initialization, and presents thepreliminary results. Multi-model ensemble experiments and analyses ofobservational data have revealed that the hydroclimatic effect of the springLST on the Tibetan Plateau is not limited to the Yangtze River basin but may have a significant large-scale impact on summer precipitation beyond EastAsia and its S2S prediction. Preliminary studies and analysis have alsoshown that LS4P models are unable to preserve the initialized LST anomaliesin producing the observed anomalies largely for two main reasons: (i) inadequacies in the land models arising from total soil depths which are tooshallow and the use of simplified parameterizations, which both tend to limit the soil memory; (ii) reanalysis data, which are used for initial conditions, have large discrepancies from the observed mean state andanomalies of LST over the Tibetan Plateau. Innovative approaches have beendeveloped to largely overcome these problems. 

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4. Dissolved Organic Carbon Mobilization Across a Climate Transect of Mesic Boreal Forests Is Explained by Air Temperature and Snowpack Duration

   https://doi.org/10.1007/s10021-022-00741-0  

   Bowering, Keri L. ; Edwards, Kate A. ; Wiersma, Yolanda F. ; Billings, Sharon A. ; Warren, Jamie ; Skinner, Andrea ; Ziegler, Susan E. ( January 2023 , Ecosystems)
5. Using strontium isotopes to trace dust from a drying Great Salt Lake to adjacent urban areas and mountain snowpack

   https://doi.org/10.1088/1748-9326/abbfc4  

   Carling, Gregory T ; Fernandez, Diego P ; Rey, Kevin A ; Hale, Colin A ; Goodman, Michael M ; Nelson, Stephen T ( November 2020 , Environmental Research Letters)

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