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

Jennings, K. S.; Kittel, Timothy G.F.; Molotch, N. P.

doi:10.5194/tc-12-1595-2018

Cited by 45 publications

(91 citation statements)

References 93 publications

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“…For this study, the combination of snow, soil, and meteorological variables resulted in the largest effective intra‐snowpack contributing area of meltwater to snow LWC at the highest elevation site, AT (Figure ). Higher elevation snowpacks will generally have higher cold content magnitudes (Jennings, Kittel, et al ()), which can refreeze surface melt produced prior to the snowpack reaching isothermal conditions. Refrozen meltwater often takes the form of ice lenses that act as permeability barriers (Webb, Fassnacht, Gooseff, et al, ) for later formation of meltwater intra‐snowpack flow paths as observed in this study (Table and Figure ).…”

Section: Discussionmentioning

confidence: 99%

“…We used the physics‐based SNOWPACK model (Bartelt & Lehning, ; Lehning, Bartelt, Brown, & Fierz, ; Lehning, Bartelt, Brown, Fierz, & Satyawali, ) to simulate snowmelt rates at the study sites. Model set‐up was the same as described in Webb, Jennings, Fend, and Molotch () and Jennings, Kittel, & Molotch () with the addition of the BTN site. We ran the model at an hourly time step using quality controlled air temperature, relative humidity, wind speed, incoming shortwave radiation, incoming longwave radiation, and snow depth data (Table ).…”

Section: Methodsmentioning

confidence: 99%

“…We estimated LW as a function of T a , RH, and SW based on the findings of Flerchinger, Xaio, Marks, Sauer, and Yu () and Jennings, Kittel, et al ().…”

Section: Methodsmentioning

confidence: 99%

“…Superscripted letters correspond to the forcing data notes as follows: a NT forcing data were derived from the nearby AT meteorological tower and corrected using a−6. (2009) and Jennings, Kittel, et al (2018). d Changes in snow depth were converted to precipitation using the approach of Hedstrom and Pomeroy (1998).…”

Section: Dye Tracer Experimentsmentioning

confidence: 99%

“…In order to obtain physically realistic results from these models, it is necessary to understand the nature of intra-snowpack flow paths and the resulting meltwater outflow variability (Webb, Williams, et al, 2018). Observed melt patterns have shown variogram ranges increase with elevation (Rikkers et al, 1996;Sommerfeld, Bales, & Mast, 1994;Webb, 2017;Jennings, Kittel, & Molotch, 2018;Williams, Sommerfeld, Massman, & Rikkers, 1999) suggesting that vegetation and other physiographic parameters influence the scale of intra-snowpack flow processes, though these studies were conducted in different locations and years making the connections to elevation and the resulting climate gradients less certain.…”

Section: Introductionmentioning

confidence: 99%

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Hydrologic connectivity at the hillslope scale through intra‐snowpack flow paths during snowmelt

Webb

Wigmore

Jennings

et al. 2020

Hydrological Processes

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The seasonal snowmelt period is a critical component of the hydrologic cycle for many mountainous areas. Changes in the timing and rate of snowmelt as a result of physical hydrologic flow paths, such as longitudinal intra‐snowpack flow paths, can have strong implications on the partitioning of meltwater amongst streamflow, groundwater recharge, and soil moisture storage. However, intra‐snowpack flow paths are highly spatially and temporally variable and thus difficult to observe. This study utilizes new methods to non‐destructively observe spatio‐temporal changes in the liquid water content of snow in combination with plot experiments to address the research question: What is the scale of influence that intra‐snowpack flow paths have on the downslope movement of liquid water during snowmelt across an elevational gradient? This research took place in northern Colorado with study plots spanning from the rain‐snow transition zone up to the high alpine. Results indicate an increasing scale of influence from intra‐snowpack flow paths with elevation, showing higher hillslope connectivity producing larger intra‐snowpack contributing areas for meltwater accumulation, quantified as the upslope contributing area required to produce observed changes in liquid water content from melt rate estimates. The total effective intra‐snowpack contributing area of accumulating liquid water was found to be 17, 6, and 0 m2 for the above tree line, near tree line, and below tree line plots, respectively. Dye tracer experiments show capillary and permeability barriers result in increased number and thickness of intra‐snowpack flow paths at higher elevations. We additionally utilized aerial photogrammetry in combination with ground penetrating radar surveys to investigate the role of this hydrologic process at the small watershed scale. Results here indicate that intra‐snowpack flow paths have influence beyond the plot scale, impacting the storage and transmission of liquid water within the snowpack at the small watershed scale.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

“…We estimated LW as a function of T a , RH, and SW based on the findings of Flerchinger, Xaio, Marks, Sauer, and Yu () and Jennings, Kittel, et al ().…”

Section: Methodsmentioning

confidence: 99%

Section: Dye Tracer Experimentsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Hydrologic connectivity at the hillslope scale through intra‐snowpack flow paths during snowmelt

Webb

Wigmore

Jennings

et al. 2020

Hydrological Processes

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Drivers and projections of ice phenology in mountain lakes in the western United States

Caldwell

Chandra

Albright

et al. 2020

Limnology & Oceanography

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Climate change is causing rapid warming and altered precipitation patterns in mountain watersheds, both of which influence the timing of ice breakup in mountain lakes. To enable predictions of ice breakup in the future, we analyzed a dataset of mountain lake ice breakup dates derived from remote sensing and historical downscaled climate data. We evaluated drivers of ice breakup, constructed a predictive statistical model, and developed projections of mountain lake ice breakup date with global climate models. Using Random Forest analysis, we determined that winter and spring cumulative snow fraction (portion of precipitation falling as snow) and air temperature are the strongest predictors of ice breakup on mountain lakes. Interactions between precipitation, cumulative winter air temperature and lake surface area indicate that shifts in air temperature and precipitation affect smaller lakes (< 2 km 2) more than larger lakes (> 2-10 km 2). A linear mixed effects model (RMSE of 18 d), applied with an ensemble of 15 global climate models, projected that end-of-century ice breakup in mountain lakes will be earlier by 25 AE 4 and 61 AE 5 (mean AE SE) days for representative concentration pathways 4.5 and 8.5, respectively.

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Models of snowmelt runoff

Maskey¹

2022

Catchment Hydrological Modelling

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

Cited by 45 publications

References 93 publications

Hydrologic connectivity at the hillslope scale through intra‐snowpack flow paths during snowmelt

Hydrologic connectivity at the hillslope scale through intra‐snowpack flow paths during snowmelt

Drivers and projections of ice phenology in mountain lakes in the western United States

Models of snowmelt runoff

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