Snow farming: conserving snow over the summer season

Grünewald, Thomas; Wolfsperger, Fabian; Lehning, Michael

doi:10.5194/tc-12-385-2018

Cited by 29 publications

(31 citation statements)

References 28 publications

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“…Terrestrial laser scanning is a well-established method to acquire high resolution elevation models of snow surfaces with a vertical accuracy of some centimeters (Prokop et al, 2008;Grünewald et al, 2010Grünewald et al, , 2018bRevuelto et al, 2014). The device deployed for this study was a Riegl VZ-6000 terrestrial laser scanner (Riegl Measurement Systems GmbH, 2018) that has been successfully applied to monitor snow surfaces and snow-height changes (dHSs) in several projects (e.g., Gabbud et al, 2015;Fischer et al, 2016;Haberkorn et al, 2017;Grünewald et al, 2018b;Mott et al, 2019). Technical specifications of the VZ6000 are listed by Fischer et al (2016) and in the Riegl data sheet (Riegl Measurement Systems GmbH, 2018).…”

Section: Calculation Of New Snow Heightmentioning

confidence: 99%

“…To avoid data gaps caused by terrain shadowing, scans were done from two to three positions. The workflow of post-processing was the same as described in Grünewald et al (2018b). For each pair of surveys, raw data were registered with four reflectors installed in the area.…”

Section: Calculation Of New Snow Heightmentioning

confidence: 99%

“…Unchanged areas (without snow accumulation) were selected for Multi Station Adjustment, a semi-automatic least square surface matching technique implemented in the processing software (Riegl Measurement Systems GmbH, 2011). This technique was successfully applied by many studies for the registration of TLS data (Carrivick et al, 2013;Sommer et al, 2015;Fischer et al, 2016;Grünewald et al, 2018b). After selecting the area of interest, a moving-window filter (octree filter) was applied to reduce the data amount and to produce a regular grid with an edge length of 10 cm.…”

Section: Calculation Of New Snow Heightmentioning

confidence: 99%

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Water Losses During Technical Snow Production: Results From Field Experiments

Grünewald¹,

Wolfsperger²

2019

Front. Earth Sci.

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Alpine as well as Nordic skiing tourism strongly depend on the production of machinemade snow for the timely opening of the winter season. However, it is likely that sublimation, evaporation, wind drift, and the discharge of unfrozen water to the ground will result in the loss of significant parts of the water used. The relation between these water losses and the ambient meteorological conditions is poorly understood. We present results from a series of 12 detailed snow-making field tests performed in a ski resort near Davos, Switzerland. Water inflows, measured at the snow machine, are related to the mass of snow deposited on the ground. Snow amounts are calculated from accumulated volumes, measured with terrestrial laser scanning (TLS), and manually sampled snow densities. Additionally, samples of liquid water contents (LWCs) of the produced snow are presented. We find that 7 to 35 ± 7% (mean 21%) of the consumed water was lost during snow-making and that the loss is strongly related to the ambient meteorological conditions. Linear regression analysis shows that water losses increase with air temperature (TA). Combining our data with observations from earlier field measurements shows similar correlations.

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Section: Calculation Of New Snow Heightmentioning

confidence: 99%

Section: Calculation Of New Snow Heightmentioning

confidence: 99%

Section: Calculation Of New Snow Heightmentioning

confidence: 99%

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Water Losses During Technical Snow Production: Results From Field Experiments

Grünewald¹,

Wolfsperger²

2019

Front. Earth Sci.

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“…Printer-friendly version Discussion paper L14: snow storage is quite expensive (see Grünewald et al 2018) L16 Besides solar radiation, air temperature is most important for snow melt (see Fig 11 in Grünewald et al 2018); precipitation is less relevant; why should evaporative cooling be higher in cold and dry climates? Evaporation is depending on the temperature gradient between surface and air, wind and wetness of the covering-layer.…”

Section: Interactive Commentmentioning

confidence: 99%

“…How is it interpreted? Add references; P7 L6-9 This explanation is too simple: heat transfer is not simply depending on air temperature; surface temperature, cloudiness (longwave radiation) and wind (turbulent fluxes) are also crucial; See discussion of simulation results in Grünewald et al 2018 and the sections about energy balance, and snow melt of the recent review paper of C7…”

Section: Interactive Commentmentioning

confidence: 99%

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Grünewald¹

2019

Preprint

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Weiss et al present a case study on over-summer snow storage (snow farming) at two sites in Vermont, US. Melt rates of two small snow piles were calculated from repeated high resolution snow volumes measured with terrestrial laser scanning (TLS). Meteorological parameters and temperatures in the covering layer were continuously measured. Moreover and they investigate the performance of different settings of covering materials (combination of wood chips, open-cell foam, rigid foam, blanket); It is shown that snow storage seems possible, even at such a low-elevation site. The novelty of the study is the high temporal resolution of the snow volume surveys (14 surveys over summer-season) and the detailed assessment of temperature gradients within the covering-material. Such data have not been presented before. Data and C1 TCD Interactive commentPrinter-friendly version Discussion paper

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Climate Change Adaptation: Capacity Building for Winter Tourism in Western Asia

Kulözü-Uzunboy¹,

Demiroglu²

2021

Encyclopedia of the UN Sustainable Development Goals

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Snow farming: conserving snow over the summer season

Cited by 29 publications

References 28 publications

Water Losses During Technical Snow Production: Results From Field Experiments

Water Losses During Technical Snow Production: Results From Field Experiments

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Climate Change Adaptation: Capacity Building for Winter Tourism in Western Asia

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