Intercomparison of BOREAS northern and southern study area surface fluxes in 1994

UBC Faculty Research and Publications

Intercomparison of BOREAS northern and southern study area surface fluxes in 1994 Black, T. Andrew; Betts, Alan K.; Barr, Alan G.; Smith, C. D.; McCaughey, J. H.

Abstract

Sensible and latent heat fluxes from the Boreal Ecosystem and Atmosphere Study (BOREAS) tower flux sites in 1994 are analyzed over both diurnal and seasonal cycles. We compare and contrast the southern and northern study areas and the behavior of five different land covers. For each land cover the evaporative fractions and surface conductances to water vapor are higher in the south than in the north, with the ranking from largest to smallest: aspen, fen, black spruce and jack pine. The conifer and, particularly, the jack pine sites show the greatest stomatal control of transpiration, as the vapor pressure deficit increases from morning to afternoon and as the soil dries during periods with low precipitation. The relation between surface conductance and the Priestley-Taylor coefficient α is consistent between southern and northern study areas but varies among land covers. The aspen and fen sites have higher α values than the landscape mean, and the mature conifer sites have lower α values than the landscape mean. We attribute the differences to the impact of spatial heterogeneity at the landscape scale. Sensible and latent heat fluxes from the Boreal Ecosystem and Atmosphere Study (BOREAS) tower flux sites in 1994 are analyzed over both diurnal and seasonal cycles. We compare and contrast the southern and northern study areas and the behavior of five different land covers. For each land cover the evaporative fractions and surface conductances to water vapor are higher in the south than in the north, with the ranking from largest to smallest: aspen, fen, black spruce and jack pine. The conifer and, particularly, the jack pine sites show the greatest stomatal control of transpiration, as the vapor pressure deficit increases from morning to afternoon and as the soil dries during periods with low precipitation. The relation between surface conductance and the Priestley-Taylor coefficient α is consistent between southern and northern study areas but varies among land covers. The aspen and fen sites have higher α values than the landscape mean, and the mature conifer sites have lower α values than the landscape mean. We attribute the differences to the impact of spatial heterogeneity at the landscape scale. An edited version of this paper was published by AGU. Copyright 2001 American Geophysical Union.

Item Metadata

Title	Intercomparison of BOREAS northern and southern study area surface fluxes in 1994
Creator	Black, T. Andrew; Betts, Alan K.; Barr, Alan G.; Smith, C. D.; McCaughey, J. H.
Publisher	American Geophysical Union
Date Issued	2001-12
Description	Sensible and latent heat fluxes from the Boreal Ecosystem and Atmosphere Study (BOREAS) tower flux sites in 1994 are analyzed over both diurnal and seasonal cycles. We compare and contrast the southern and northern study areas and the behavior of five different land covers. For each land cover the evaporative fractions and surface conductances to water vapor are higher in the south than in the north, with the ranking from largest to smallest: aspen, fen, black spruce and jack pine. The conifer and, particularly, the jack pine sites show the greatest stomatal control of transpiration, as the vapor pressure deficit increases from morning to afternoon and as the soil dries during periods with low precipitation. The relation between surface conductance and the Priestley-Taylor coefficient α is consistent between southern and northern study areas but varies among land covers. The aspen and fen sites have higher α values than the landscape mean, and the mature conifer sites have lower α values than the landscape mean. We attribute the differences to the impact of spatial heterogeneity at the landscape scale. Sensible and latent heat fluxes from the Boreal Ecosystem and Atmosphere Study (BOREAS) tower flux sites in 1994 are analyzed over both diurnal and seasonal cycles. We compare and contrast the southern and northern study areas and the behavior of five different land covers. For each land cover the evaporative fractions and surface conductances to water vapor are higher in the south than in the north, with the ranking from largest to smallest: aspen, fen, black spruce and jack pine. The conifer and, particularly, the jack pine sites show the greatest stomatal control of transpiration, as the vapor pressure deficit increases from morning to afternoon and as the soil dries during periods with low precipitation. The relation between surface conductance and the Priestley-Taylor coefficient α is consistent between southern and northern study areas but varies among land covers. The aspen and fen sites have higher α values than the landscape mean, and the mature conifer sites have lower α values than the landscape mean. We attribute the differences to the impact of spatial heterogeneity at the landscape scale. An edited version of this paper was published by AGU. Copyright 2001 American Geophysical Union.
Genre	Article
Type	Text
Language	eng
Date Available	2011-05-25
Provider	Vancouver : University of British Columbia Library
Rights	Attribution-NonCommercial-NoDerivatives 4.0 International
DOI	10.14288/1.0041928
URI	http://hdl.handle.net/2429/34823
Affiliation	Land and Food Systems, Faculty of
Citation	Barr, Alan G.; Betts, Alan K.; Black, T. Andrew; McCaughey, J. H.; Smith, C. D. 2001. Intercomparison of BOREAS northern and southern study area surface fluxes in 1994. 2001. Journal of Geophysical Research Atmospheres 106(D24), 33, 543–33, 550.
Publisher DOI	10.1029/2001JD900070
Peer Review Status	Reviewed
Scholarly Level	Faculty
Copyright Holder	Black, T. Andrew
Rights URI	http://creativecommons.org/licenses/by-nc-nd/4.0/
Aggregated Source Repository	DSpace

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