Dropstones in Lacustrine Sediments as a Record of Snow Avalanches—A Validation of the Proxy by Combining Satellite Imagery and Varve Chronology at Kenai Lake (South-Central Alaska)

Snow avalanches cause many fatalities every year and damage local economies worldwide. The present-day climate change affects the snowpack and, thus, the properties and frequency of snow avalanches. Reconstructing snow avalanche records can help us understand past variations in avalanche frequency and their relationship to climate change. Previous avalanche records have primarily been reconstructed using dendrochronology. Here, we investigate the potential of lake sediments to record snow avalanches by studying 27 < 30-cm-long sediment cores from Kenai Lake, south-central Alaska. We use X-ray computed tomography (CT) to image post-1964 varves and to identify dropstones. We use two newly identified cryptotephras to update the existing varve chronology. Satellite imagery is used to understand the redistribution of sediments by ice floes over the lake, which helps to explain why some avalanches are not recorded. Finally, we compare the dropstone record with climate data to show that snow avalanche activity is related to high amounts of snowfall in periods of relatively warm or variable temperature conditions. We show, for the first time, a direct link between historical snow avalanches and dropstones preserved in lake sediments. Although the lacustrine varve record does not allow for the development of a complete annual reconstruction of the snow avalanche history in the Kenai Lake valley, our results suggest that it can be used for long-term decadal reconstructions of the snow-avalanche history, ideally in combination with similar records from lakes elsewhere in the region.

[1]  X. Montet,et al.  Wet avalanches: long-term evolution in the Western Alps under climate and human forcing , 2018, Climate of the Past.

[2]  J. Madrigal‐González,et al.  Climate warming enhances snow avalanche risk in the Western Himalayas , 2018, Proceedings of the National Academy of Sciences.

[3]  S. Schmidt,et al.  Varve formation during the past three centuries in three large proglacial lakes in south-central Alaska , 2017 .

[4]  J. Moernaut,et al.  A revised classification and terminology for stacked and amalgamated turbidites in environments dominated by (hemi)pelagic sedimentation , 2017 .

[5]  X. Montet,et al.  A new CT scan methodology to characterize a small aggregation gravel clast contained in a soft sediment matrix , 2017 .

[6]  S. Schmidt,et al.  Paleoseismic potential of sublacustrine landslide records in a high-seismicity setting (south-central Alaska) , 2017 .

[7]  D. Froese,et al.  Late Pleistocene and Holocene tephrostratigraphy of interior Alaska and Yukon: Key beds and chronologies over the past 30,000 years , 2016 .

[8]  Mauro Valt,et al.  Avalanche fatalities in the European Alps: long-term trends and statistics , 2016 .

[9]  Rajiv Gupta,et al.  Computed tomography imaging and angiography - principles. , 2016, Handbook of clinical neurology.

[10]  A. Schimmelmann,et al.  Varves in lake sediments – a review , 2015 .

[11]  D. Froese,et al.  First evidence of cryptotephra in palaeoenvironmental records associated with Norse occupation sites in Greenland , 2015 .

[12]  Veerle Cnudde,et al.  High-resolution X-ray computed tomography in geosciences: A review of the current technology and applications , 2013 .

[13]  G. Plafker,et al.  Paleoseismicity and Neotectonics of the Aleutian Subduction Zone—An Overview , 2013 .

[14]  Kevin W Eliceiri,et al.  NIH Image to ImageJ: 25 years of image analysis , 2012, Nature Methods.

[15]  A. Nesje,et al.  A Holocene record of snow-avalanche and flood activity reconstructed from a lacustrine sedimentary sequence in Oldevatnet, western Norway , 2011 .

[16]  Veerle Cnudde,et al.  Three-Dimensional Analysis of High-Resolution X-Ray Computed Tomography Data with Morpho+ , 2011, Microscopy and Microanalysis.

[17]  J. Schweizer,et al.  Characteristics of wet-snow avalanche activity: 20 years of observations from a high alpine valley (Dischma, Switzerland) , 2009 .

[18]  C. F. Sawyer,et al.  Dendrogeomorphology and high-magnitude snow avalanches: a review and case study , 2008 .

[19]  S. Dahl,et al.  A continuous, high-resolution 8500-yr snow-avalanche record from western Norway , 2007 .

[20]  P. Wallace,et al.  Storage and interaction of compositionally heterogeneous magmas from the 1986 eruption of Augustine Volcano, Alaska , 2006 .

[21]  B. Jamieson Formation of refrozen snowpack layers and their role in slab avalanche release , 2006 .

[22]  David G. E. Liverman,et al.  Snow Avalanche Hazard in Canada – a Review , 2003 .

[23]  M. L. Miller,et al.  Geologic signature of early Tertiary ridge subduction in Alaska , 2003 .

[24]  S. Dahl,et al.  Holocene glacier fluctuations of Grovabreen and Holocene snow-avalanche activity reconstructed from lake sediments in Grningstlsvatnet, western Norway , 2002 .

[25]  D. Mcclung,et al.  The Avalanche Handbook , 1993 .

[26]  D. Atkins Colorado Avalanche Information Center , 1992 .

[27]  R. Waitt,et al.  Stratigraphy, chronology, and character of the 1976 pyroclastic eruption of Augustine volcano, Alaska , 1991 .

[28]  B. R. Jennings,et al.  Particle size measurement: the equivalent spherical diameter , 1988, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.

[29]  G. Malanson,et al.  A HISTORY OF HIGH-MAGNITUDE SNOW AVALANCHES, SOUTHERN GLACIER NATIONAL PARK, MONTANA, U.S.A. , 1985 .

[30]  Stephen Self,et al.  Ukinrek Maars, Alaska, II. Deposits and formation of the 1977 craters , 1980 .

[31]  Stephen Self,et al.  Ukinrek Maars, Alaska, I. April 1977 eruption sequence, petrology and tectonic setting , 1980 .

[32]  B. Luckman,et al.  Drop Stones Resulting From Snow-Avalanche Deposition On Lake Ice , 1975, Journal of Glaciology.

[33]  L. H.,et al.  Snow Structure and Ski Fields , 1936, Nature.