Evidence for Elevation-Dependent Warming in the St. Elias Mountains, Yukon, Canada

Evidence for Elevation-Dependent Warming in the St. Elias Mountains, Yukon, Canada

The climate of high midlatitude mountains appears to be warming faster than the global average, but evidence for such elevation-dependent warming (EDW) at higher latitudes is presently scarce. Here, we use a comprehensive network of remote meteorological stations, proximal radiosonde measurements, d...

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Bibliographic Details
Published in:Journal of climate Vol. 33; no. 8; pp. 3253 - 3269
Main Authors: Williamson, Scott N., Zdanowicz, Christian, Anslow, Faron S., Clarke, Garry K. C., Copland, Luke, Danby, Ryan K., Flowers, Gwenn E., Holdsworth, Gerald, Jarosch, Alexander H., Hik, David S.
Format: Journal Article
Language:English
Published: Boston American Meteorological Society 15-04-2020
Subjects:
Air temperature
Albedo
Albedo (solar)
Canada
Climate
climate change
Climatic indexes
Cores
Earth Science with specialization in Physical Geography
Elevation
Feedback
Geovetenskap med inriktning mot naturgeografi
Ice cores
Latitude
Long wave radiation
Mean sea level
Mixing ratio
Mountain climates
Mountains
Radiation
Radiative forcing
Radiosondes
Satellite data
Sea level
subarctic
Sulfate aerosols
Sulfates
Summer
Surface temperature
Surface-air temperature relationships
Temperature
Trend analysis
Trends
Troposphere
Water vapor
Water vapour
Weather stations
Alps
Tibetan Plateau
Canada
United States > US
Arctic region
Alaska
North America
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Summary:The climate of high midlatitude mountains appears to be warming faster than the global average, but evidence for such elevation-dependent warming (EDW) at higher latitudes is presently scarce. Here, we use a comprehensive network of remote meteorological stations, proximal radiosonde measurements, downscaled temperature reanalysis, ice cores, and climate indices to investigate the manifestation and possible drivers of EDW in the St. Elias Mountains in subarctic Yukon, Canada. Linear trend analysis of comprehensively validated annual downscaled North American Regional Reanalysis (NARR) gridded surface air temperatures for the years 1979–2016 indicates a warming rate of 0.028°C a−1 between 5500 and 6000 m above mean sea level (MSL), which is ∼1.6 times larger than the global-average warming rate between 1970 and 2015. The warming rate between 5500 and 6000 m MSL was ∼1.5 times greater than the rate at the 2000–2500 m MSL bin (0.019°C a−1), which is similar to the majority of warming rates estimated worldwide over similar elevation gradients. Accelerated warming since 1979, measured by radiosondes, indicates a maximum rate at 400 hPa (~7010 m MSL). EDW in the St. Elias region therefore appears to be driven by recent warming of the free troposphere. MODIS satellite data show no evidence for an enhanced snow albedo feedback above 2500 m MSL, and declining trends in sulfate aerosols deposited in high-elevation ice cores suggest a modest increase in radiative forcing at these elevations. In contrast, increasing trends in water vapor mixing ratio at the 500-hPa level measured by radiosonde suggest that a longwave radiation vapor feedback is contributing to EDW.
ISSN:0894-8755
1520-0442
1520-0442
DOI:10.1175/JCLI-D-19-0405.1