Effects of needleleaf forest cover on radiation and snowmelt dynamics in the Canadian Rocky Mountains

Radiation is the main energy source for snowpack warming and melt in mountain needleleaf forests, and runoff from these forests is the main contributor to spring river flows in western North America. Utilizing extensive field observations, the effect of needleleaf forest cover on radiation and snowm...

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Bibliographic Details
Published inCanadian journal of forest research Vol. 41; no. 3; pp. 608 - 620
Main Authors Ellis, C.R, Pomeroy, J.W, Essery, R.L.H, Link, T.E
Format Journal Article
LanguageEnglish
Published Ottawa, ON NRC Research Press, National Research Council Canada 01.03.2011
National Research Council of Canada
NRC Research Press
Canadian Science Publishing NRC Research Press
Subjects
Biological and medical sciences
energy
Energy sources
Environmental aspects
Forestry
Forests
Fundamental and applied biological sciences. Psychology
melting
Mountain forests
Mountains
Radiation
River flow
rivers
runoff
Slopes
snow
Snowmelt
Snowpack
Surface-ice melting
Vegetation
North America
Rocky Mountain region
Rocky Mountains
America
Canada
Forests
Plant cover
Dynamic characteristic
Mountain
Forestry
Radiation
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Summary:Radiation is the main energy source for snowpack warming and melt in mountain needleleaf forests, and runoff from these forests is the main contributor to spring river flows in western North America. Utilizing extensive field observations, the effect of needleleaf forest cover on radiation and snowmelt timing was quantified at pine and spruce forest sites and nearby clearings of varying slope and aspect in an eastern Canadian Rocky Mountain headwater basin. Compared with open clearing sites, shortwave radiation was much reduced under forest cover, resulting in smaller differences in melt timing between forested slopes relative to open slopes with different aspects. In contrast, longwave radiation to snow was substantially enhanced under forest cover, especially at the dense spruce forest sites where longwave radiation dominated total energy for snowmelt. In both pine and spruce environments, forest cover acted to substantially reduce total radiation to snow and delay snowmelt timing on south-facing slopes while increasing total radiation and advancing snowmelt timing on north-facing slopes. Results strongly suggest that impacts on radiation to snow and snowmelt timing from changes in mountain forest cover will depend much on the slope and aspect at which changes occur.
Bibliography:http://dx.doi.org/10.1139/X10-227
ISSN:0045-5067
1208-6037
DOI:10.1139/x10-227