Rain versus Snow in the Sierra Nevada, California: Comparing Doppler Profiling Radar and Surface Observations of Melting Level

Lundquist, Jessica D.; Neiman, Paul J.; Martner, Brooks E.; White, Allen B.; Gottas, Daniel J.; Ralph, F. Martin

doi:10.1175/2007jhm853.1

Cited by 135 publications

(166 citation statements)

References 32 publications

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“…A melting-level error of 500 m can result in a 200% difference in peak flow prediction [White et al, 2002]. Previous studies interpolated ground melting elevation from atmosphere hydrometeor measurements using Doppler-profiling radar [Lundquist et al, 2008;Minder and Kingsmill, 2012]. However, the uncertainty in estimates made from these methods were at best about 300 m in the American River basin.…”

Section: Discussionmentioning

confidence: 99%

“…Therefore, using a dew-point temperature-based method to determine the phase of precipitation is generally less geographically dependent [Ye et al, 2013]. It has also been observed that using ground-based dew-point temperatures to determine the phase of precipitation is potentially more accurate than radar-based methods due to reduction of error associate to interpreting the radar measurement [Lundquist et al, 2008].…”

Section: Introductionmentioning

confidence: 99%

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Insights into mountain precipitation and snowpack from a basin‐scale wireless‐sensor network

Zhang

Glaser

Bales

et al. 2017

Water Resources Research

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A spatially distributed wireless‐sensor network, installed across the 2154 km2 portion of the 5311 km2 American River basin above 1500 m elevation, provided spatial measurements of temperature, relative humidity, and snow depth in the Sierra Nevada, California. The network consisted of 10 sensor clusters, each with 10 measurement nodes, distributed to capture the variability in topography and vegetation cover. The sensor network captured significant spatial heterogeneity in rain versus snow precipitation for water‐year 2014, variability that was not apparent in the more limited operational data. Using daily dew‐point temperature to track temporal elevational changes in the rain‐snow transition, the amount of snow accumulation at each node was used to estimate the fraction of rain versus snow. This resulted in an underestimate of total precipitation below the 0°C dew‐point elevation, which averaged 1730 m across 10 precipitation events, indicating that measuring snow does not capture total precipitation. We suggest blending lower elevation rain gauge data with higher‐elevation sensor‐node data for each event to estimate total precipitation. Blended estimates were on average 15–30% higher than using either set of measurements alone. Using data from the current operational snow‐pillow sites gives even lower estimates of basin‐wide precipitation. Given the increasing importance of liquid precipitation in a warming climate, a strategy that blends distributed measurements of both liquid and solid precipitation will provide more accurate basin‐wide precipitation estimates, plus spatial and temporal patters of snow accumulation and melt in a basin.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Insights into mountain precipitation and snowpack from a basin‐scale wireless‐sensor network

Zhang

Glaser

Bales

et al. 2017

Water Resources Research

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“…His equations account for: (1) Heat exchange resulting from gas, liquid, or solid phase change; (2) Change in particle mass by condensation; (3) The resulting latent heat flux from condensation; (4) Heat exchange from collision coalescence or through accretion of liquid and ice crystals; and (5) Latent heat of fusion with particles melting or freezing due to contact with each other. Detailed examples of more complicated microphysical schemes are found in e.g., Thériault and Stewart [26] or Lundquist [28].…”

Section: Hydrometeor Interactionsmentioning

confidence: 99%

“…All surface-based PPDS approaches assume a constant decrease in air temperature with height (e.g., the Climate High Resolution Model (CHRM)-7.5 °C/km) [16] and do not account for interactions either between warm and cold air masses found in the most basic mid-latitude cyclone theories, or between hydrometeors and the air as precipitation falls through the lower atmosphere [28]. Therefore, without atmospheric measurements, the most physically based surface PPDS methods can not accurately reproduce physical processes occurring between hydrometeors and the atmosphere they fall through.…”

Section: Introductionmentioning

confidence: 99%

Meteorological Knowledge Useful for the Improvement of Snow Rain Separation in Surface Based Models

et al. 2015

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An accurate precipitation phase determination-i.e., solid versus liquid-is of paramount importance in a number of hydrological, ecological, safety and climatic applications. Precipitation phase can be determined by hydrological, meteorological or combined approaches. Meteorological approaches require atmospheric data that is not often utilized in the primarily surface based hydrological or ecological models. Many surface based models assign precipitation phase from surface temperature dependent snow fractions, which assume that atmospheric conditions acting on hydrometeors falling through the lower atmosphere are invariant. This ignores differences in phase change probability caused by air mass boundaries which can introduce a warm air layer over cold air leading to more atmospheric melt energy than expected for a given surface temperature, differences in snow grain-size or precipitation rate which increases the magnitude of latent heat exchange between the hydrometers and atmosphere required to melt the snow resulting in snow at warmer temperatures, or earth surface properties near a surface observation point heating or cooling a shallow layer of air allowing rain at cooler temperatures or snow at warmer OPEN ACCESSHydrology 2015, 2 267 temperatures. These and other conditions can be observed or inferred from surface observations, and should therefore be used to improve precipitation phase determination in surface models.

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“…However, the underlying phase prediction method and related model decisions and climate forcing data can also be important for the quality of precipitation 10 phase prediction (Harpold et al, 2017). Further complicating rain-snow transition mechanisms is storage or drainage of liquid water in the snowpacks (Lundquist et al, 2008;Marks et al, 2001). Although SNODAS assimilates MODIS imagery into the model, it does not appear to capture the finer elevation patterns we found using the MOD10A product (Fig.…”

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confidence: 99%

Now You See It Now You Don’t: A Case Study of Ephemeral Snowpacks in the Great Basin U.S.A.

Petersky

Harpold

2018

Preprint

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Ephemeral snowpacks, or those that routinely experience accumulation and ablation at the same time and persist for <60 days, are challenging to observe and model. Using 328 site years from the Great Basin, we show that ephemeral snowmelt delivers water earlier than seasonal snowmelt. For example, we found that day of peak soil moisture preceded day of last snowmelt in the Great Basin by 79 days for shallow soil moisture in ephemeral snowmelt compared to 5 days for seasonal snowmelt. To 5 understand Great Basin snow distribution, we used moderate resolution imaging spectroradiometer (MODIS) and Snow Data Assimilation System (SNODAS) data from water years 2005-2014 to map snow extent. During this time period snowpack was highly variable. The maximum seasonal snow cover was 64 % in 2010 and the minimum was 24 % in 2014. We found that elevation had a strong control on snow ephemerality, and nearly all snowpacks over 2500 m were seasonal. Snowpacks were more likely to be ephemeral on south facing slopes than north facing slopes at elevations above 2500 m. Additionally, we 10 used SNODAS-derived estimates of solid and liquid precipitation, melt, sublimation, and blowing snow sublimation to define snow ephemerality mechanisms. In warm years, the Great Basin shifts to ephemerally dominant as the rain-snow transition increases in elevation. Given that snow ephemerality is expected to increase as a consequence of climate change, we put forward several challenges and recommendations to bolster physics based modeling of ephemeral snow such as better metrics for snow ephemerality and more ground-based observations. 15 IntroductionSeasonal snowmelt supplies water to one-sixth of the world's population, which supports one-fourth of the global economy (Barnett et al., 2005;Sturm et al., 2017). Seasonal snowpack provides predictable melt timing and volumes in the spring, which influences streamflow timing, surface water and groundwater availability (Berghuijs et al., 2014;Jasechko et al., 2014;Stewart et al., 2005). Reliable spring snowmelt also provides a strong control on vegetation phenology and productivity in many 20 ecosystems (Parida and Buermann, 2014;Trujillo et al., 2012). Despite the importance of seasonal snow to water supplies, much of the world's snow is ephemeral, which means it melts and sublimates throughout the snow cover season instead of having one consistent period of snowmelt. Even small shifts from seasonal to ephemeral snowpack due to regional warming could disrupt 1 Hydrol. Earth Syst. Sci. Discuss., https://doi.org/10.5194/hess-2017-749 Manuscript under review for journal Hydrol. Earth Syst. Sci. Discussion started: 8 January 2018 c Author(s) 2018. CC BY 4.0 License. snowmelt timing in ways that could alter summer productivity, soil temperature, and soil moisture regimes Harpold and Molotch, 2015;Jefferson, 2011;Parida and Buermann, 2014;Regonda et al., 2005;Stielstra et al., 2015;Trujillo et al., 2012). A shift from seasonal to ephemeral snowpacks will also have negative implications for the wi...

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Rain versus Snow in the Sierra Nevada, California: Comparing Doppler Profiling Radar and Surface Observations of Melting Level

Cited by 135 publications

References 32 publications

Insights into mountain precipitation and snowpack from a basin‐scale wireless‐sensor network

Insights into mountain precipitation and snowpack from a basin‐scale wireless‐sensor network

Meteorological Knowledge Useful for the Improvement of Snow Rain Separation in Surface Based Models

Now You See It Now You Don’t: A Case Study of Ephemeral Snowpacks in the Great Basin U.S.A.

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