Active Filters

  • (-) Keywords = avalanche
Search Results 1 - 20 of 44
Select Page
Formation of long-distance water ice avalanches on mars
Krasilnikov, S. S., Kuzmin, R. O., Bühler, Y., & Zabalueva, E. V. (2020). Formation of long-distance water ice avalanches on mars. Planetary and Space Science, 186, 104917 (10 pp.). https://doi.org/10.1016/j.pss.2020.104917
Temporal changes in the mechanical properties of snow related to crack propagation after loading
Birkeland, K. W., van Herwijnen, A., Reuter, B., & Bergfeld, B. (2019). Temporal changes in the mechanical properties of snow related to crack propagation after loading. Cold Regions Science and Technology, 159, 142-152. https://doi.org/10.1016/j.coldregions.2018.11.007
Numerical investigation of the mixed-mode failure of snow
Mulak, D., & Gaume, J. (2019). Numerical investigation of the mixed-mode failure of snow. Computational Particle Mechanics, 6, 439-447. https://doi.org/10.1007/s40571-019-00224-5
Snow entrainment: avalanche interaction with an erodible substrate
Bartelt, P., Christen, M., Bühler, Y., Caviezel, A., & Buser, O. (2018). Snow entrainment: avalanche interaction with an erodible substrate. In International snow science workshop proceedings 2018 (pp. 716-720). Retrieved from http://arc.lib.montana.edu/snow-science/item/2633
Snow stabilization following storms: field experiments and modelling of temporal changes in snow mechanical properties following loading
Birkeland, K. W., van Herwijnen, A., Reuter, B., & Bergfeld, B. (2018). Snow stabilization following storms: field experiments and modelling of temporal changes in snow mechanical properties following loading. In International snow science workshop proceedings 2018 (pp. 861-865). Retrieved from http://arc.lib.montana.edu/snow-science/item/2665
The influence of snow physical properties on humans breathing into an artificial air pocket
Gatterer, H., Strapazzon, G., Dal Cappello, T., Schenk, K., Paal, P., Falk, M., … Brugger, H. (2018). The influence of snow physical properties on humans breathing into an artificial air pocket. In International snow science workshop proceedings 2018 (pp. 1414-1416). Retrieved from http://arc.lib.montana.edu/snow-science/item/2786
Avalanche pressures at the Vallée de la Sionne test site: interaction of avalanches and narrow structures studied withe DEM
Kyburz, M., Sovilla, B., Gaume, J., & Ancey, C. (2018). Avalanche pressures at the Vallée de la Sionne test site: interaction of avalanches and narrow structures studied withe DEM. In International snow science workshop proceedings 2018 (pp. 40-42). Retrieved from http://arc.lib.montana.edu/snow-science/item/2482
Automated identification of forest with protective function against snow avalanches in the Trento province (Italy)
Monti, F., Alberti, R., Comin, P., Wolynski, A., Vallata, L., & Bühler, Y. (2018). Automated identification of forest with protective function against snow avalanches in the Trento province (Italy). In International snow science workshop proceedings 2018 (pp. 731-735). Retrieved from http://arc.lib.montana.edu/snow-science/item/2636
Infrasound detection of avalanches: operational experience from 28 combined winter seasons and future developments
Steinkogler, W., Ulivieri, G., Vezzosi, S., Hendrikx, J., van Herwijnen, A., & Humstad, T. (2018). Infrasound detection of avalanches: operational experience from 28 combined winter seasons and future developments. In International snow science workshop proceedings 2018 (pp. 621-626). Retrieved from http://arc.lib.montana.edu/snow-science/item/2612
Schutzwald bei veränderten Umweltbedingungen
Bebi, P., Kreiner, M., & Fuchs, J. (2017). Schutzwald bei veränderten Umweltbedingungen. Wildbach- und Lawinenverbau, 81(179), 162-173.
Построение цифровой модели рельефа Марса по данным сканерной съемочной системы Context Camera (CTX) длядальнейшего геолого-геоморфологического анализа
Krasilnikov, S. S., Brusnikin, E. S., Zubarev, A. E., Bühler, Y., & Kuzmin, R. O. (2017). Построение цифровой модели рельефа Марса по данным сканерной съемочной системы Context Camera (CTX) длядальнейшего геолого-геоморфологического анализа. Sovremennye problemy distantsionnogo zondirovaniya Zemli iz kosmosa, 14(4), 265-272. https://doi.org/10.21046/2070-7401-2017-14-4-265-272
Avalanche accidents causing fatalities: are they any different in the summer?
Pasquier, M., Hugli, O., Kottmann, A., & Techel, F. (2017). Avalanche accidents causing fatalities: are they any different in the summer? High Altitude Medicine & Biology, 18(1), 67-72. https://doi.org/10.1089/ham.2016.0065
Snowpack response to directed gas explosions on level ground
Simioni, S., Dual, J., & Schweizer, J. (2017). Snowpack response to directed gas explosions on level ground. Cold Regions Science and Technology, 144, 73-88. https://doi.org/10.1016/j.coldregions.2017.09.012
Evaluation of protection measures against avalanches in forested terrain
Feistl, T., Fischer, A., Bebi, P., & Bartelt, P. (2016). Evaluation of protection measures against avalanches in forested terrain. In ISSW proceedings. International snow science workshop proceedings 2016 (pp. 561-568). Retrieved from http://arc.lib.montana.edu/snow-science/item/2323
Quantifying the effectiveness of active mitigation on transportation corridors
Hamre, D., Greene, E., & Margreth, S. (2016). Quantifying the effectiveness of active mitigation on transportation corridors. In ISSW proceedings. International snow science workshop proceedings 2016 (pp. 435-441). Retrieved from http://arc.lib.montana.edu/snow-science/item/2304
Burial duration, depth and air pocket explain avalanche survival patterns in Austria and Switzerland
Procter, E., Strapazzon, G., Dal Cappello, T., Zweifel, B., Würtele, A., Renner, A., … Brugger, H. (2016). Burial duration, depth and air pocket explain avalanche survival patterns in Austria and Switzerland. Resuscitation, 105, 173-176. https://doi.org/10.1016/j.resuscitation.2016.06.001
Powder snow avalanche engineering: new methods to calculate air-blast pressures for hazard mapping
Stoffel, L., Margreth, S., Schaer, M., Christen, M., Bühler, Y., & Bartelt, P. (2016). Powder snow avalanche engineering: new methods to calculate air-blast pressures for hazard mapping. In G. Koboltschnig (Ed.), 13th congress INTERPRAEVENT 2016. 30 May to 2 June 2016. Lucerne, Switzerland. Conference proceedings "Living with natural risks" (pp. 416-425). Retrieved from http://www.interpraevent.at/?tpl=tagungsbaende_detail.php&band_id=2720&menu=221
Using 2 m extended column tests to assess slope stability
Bair, E. H., Simenhois, R., van Herwijnen, A., & Birkeland, K. W. (2015). Using 2 m extended column tests to assess slope stability. Cold Regions Science and Technology, 120, 191-196. https://doi.org/10.1016/j.coldregions.2015.06.021
West Twin avalanche helicopter involvement - How safe are our pick-up locations?
Honig, J., Bartelt, P., & Bühler, Y. (2014). West Twin avalanche helicopter involvement - How safe are our pick-up locations? In ISSW proceedings. International snow science workshop proceedings 2014 (pp. 356-363). Retrieved from http://arc.lib.montana.edu/snow-science/item/2078
Applying the avalanche terrain exposure scale in the Swiss Jura mountains
Pielmeier, C., Silbernagel, D., Dürr, L., & Stucki, T. (2014). Applying the avalanche terrain exposure scale in the Swiss Jura mountains. In ISSW proceedings. International snow science workshop proceedings 2014 (pp. 883-889). Retrieved from http://arc.lib.montana.edu/snow-science/item/2170