Synoptic Climatology of Rain-on-Snow Events in Alaska

Rain-on-snow (ROS) events can have adverse impacts on high-latitude ungulate populations when rain freezes in the snowpack, forming ice layers that block access to winter forage. In extreme cases, ROS events have led to mass die-offs. ROS events are linked to advection of warm and moist air, associa...

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Bibliographic Details
Published in:Monthly weather review 2020-03, Vol.148 (3), p.1275-1295
Main Authors: Crawford, Alex D., Alley, Karen E., Cooke, Anna M., Serreze, Mark C.
Format: Article
Language:English
Subjects:
Advection
Anomalies
Anticyclones
Atmospheric blocking
Atmospheric precipitations
Blocking
Caribou
Climatology
Cyclones
Extratropical cyclones
Floods
Ice formation
Precipitable water
Precipitation
Pressure
Pressure gradients
Rain
Reindeer
Sea level
Sea level pressure
Snow
Snowpack
Storms
Synoptic climatology
Winter
Winter precipitation
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Summary:Rain-on-snow (ROS) events can have adverse impacts on high-latitude ungulate populations when rain freezes in the snowpack, forming ice layers that block access to winter forage. In extreme cases, ROS events have led to mass die-offs. ROS events are linked to advection of warm and moist air, associated with extratropical cyclones. However, these conditions are common to many winter precipitation events, challenging our understanding of the particular conditions under which ROS events occur. This study uses the Modern-Era Retrospective Analysis for Research and Applications version 2 (MERRA-2) to differentiate ROS events in Alaska from precipitation events in which only snow falls on a preexisting snowpack [snow-on-snow (SOS)]. Over the North Slope and Kotzebue Sound, no clear difference exists between the tracks of ROS-producing and SOS-producing storms. However, in the interior, southwest, and Anchorage, tracks of ROS-producing storms tend to be farther north and west than for SOS-producing storms. The northwest shift of ROS-producing storms is linked to the position of upper-tropospheric anticyclones in the eastern Gulf of Alaska during ROS events. ROS-producing storms are no more intense than SOS-producing storms, but their association with atmospheric blocking leads to stronger pressure gradients on the east side of storms and thereby stronger advection of positive anomalies in temperature and precipitable water. For several sites, sea level pressure in the eastern Gulf of Alaska is also significantly higher a few days prior to ROS events than prior to SOS events, further implicating atmospheric blocking as a facilitator and potential predictor of ROS events.
ISSN:0027-0644
1520-0493
DOI:10.1175/MWR-D-19-0311.1