| Autor: |
Peitzsch EH; U.S. Geological Survey Northern Rocky Mountain Science Center, 215 Mather Dr., West Glacier, MT, 59936, USA. epeitzsch@usgs.gov.; Snow and Avalanche Lab, Department of Earth Sciences, Montana State University, Bozeman, MT, USA. epeitzsch@usgs.gov., Pederson GT; U.S. Geological Survey Northern Rocky Mountain Science Center, 215 Mather Dr., West Glacier, MT, 59936, USA., Birkeland KW; Snow and Avalanche Lab, Department of Earth Sciences, Montana State University, Bozeman, MT, USA.; U.S.D.A. Forest Service National Avalanche Center, Bozeman, MT, USA., Hendrikx J; Snow and Avalanche Lab, Department of Earth Sciences, Montana State University, Bozeman, MT, USA., Fagre DB; U.S. Geological Survey Northern Rocky Mountain Science Center, 215 Mather Dr., West Glacier, MT, 59936, USA. |
| Abstrakt: |
Large magnitude snow avalanches pose a hazard to humans and infrastructure worldwide. Analyzing the spatiotemporal behavior of avalanches and the contributory climate factors is important for understanding historical variability in climate-avalanche relationships as well as improving avalanche forecasting. We used established dendrochronological methods to develop a long-term (1867-2019) regional avalanche chronology for the Rocky Mountains of northwest Montana using tree-rings from 647 trees exhibiting 2134 avalanche-related growth disturbances. We then used principal component analysis and a generalized linear autoregressive moving average model to examine avalanche-climate relationships. Historically, large magnitude regional avalanche years were characterized by stormy winters with positive snowpack anomalies, with avalanche years over recent decades increasingly influenced by warmer temperatures and a shallow snowpack. The amount of snowpack across the region, represented by the first principal component, is shown to be directly related to avalanche probability. Coincident with warming and regional snowpack reductions, a decline of ~ 14% (~ 2% per decade) in overall large magnitude avalanche probability is apparent through the period 1950-2017. As continued climate warming drives further regional snowpack reductions in the study region our results suggest a decreased probability of regional large magnitude avalanche frequency associated with winters characterized by large snowpacks and a potential increase in large magnitude events driven by warming temperatures and spring precipitation. |
