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Climatic controls on the carbon and water balances of a boreal aspen forest, 1994–2003.

Authors :
BARR, ALAN G.
BLACK, T. A.
HOGG, E. H.
GRIFFIS, T. J.
MORGENSTERN, K.
KLJUN, N.
THEEDE, A.
NESIC, Z.
Source :
Global Change Biology; Mar2007, Vol. 13 Issue 3, p561-576, 16p, 2 Charts, 8 Graphs
Publication Year :
2007

Abstract

The carbon and water budgets of boreal and temperate broadleaf forests are sensitive to interannual climatic variability and are likely to respond to climate change. This study analyses 9 years of eddy-covariance data from the Boreal Ecosystem Research and Monitoring Sites (BERMS) Southern Old Aspen site in central Saskatchewan, Canada and characterizes the primary climatic controls on evapotranspiration, net ecosystem production ( F<subscript>NEP</subscript>), gross ecosystem photosynthesis ( P) and ecosystem respiration ( R). The study period was dominated by two climatic extremes: extreme warm and cool springs, which produced marked contrasts in the canopy duration, and a severe, 3-year drought. Annual F<subscript>NEP</subscript> varied among years from 55 to 367 g C m<superscript>−2</superscript> (mean 172, SD 94). Interannual variability in F<subscript>NEP</subscript> was controlled primarily by factors that affected the R/ P ratio, which varied between 0.74 and 0.96 (mean 0.87, SD 0.06). Canopy duration enhanced P and F<subscript>NEP</subscript> with no apparent effect on R. The fraction of annual photosynthetically active radiation (PAR) that was absorbed by the canopy foliage varied from 38% in late leaf-emergence years to 51% in early leaf-emergence years. Photosynthetic light-use efficiency (mean 0.0275, SD 0.026 mol C mol<superscript>−1</superscript> photons) was relatively constant during nondrought years but declined with drought intensity to a minimum of 0.0228 mol C mol<superscript>−1</superscript> photons during the most severe drought year. The impact of drought on F<subscript>NEP</subscript> varied with drought intensity. Years of mild-to-moderate drought suppressed R while having little effect on P, so that F<subscript>NEP</subscript> was enhanced. Years of severe drought suppressed both R and P, causing either little change or a subtle reduction in F<subscript>NEP</subscript>. The analysis produced new insights into the dominance of canopy duration as the most important biophysical control on F<subscript>NEP</subscript>. The results suggested a simple conceptual model for annual F<subscript>NEP</subscript> in boreal deciduous forests. When water is not limiting, annual P is controlled by canopy duration via its influence on absorbed PAR at constant light-use efficiency. Water stress suppresses P, by reducing light-use efficiency, and R, by limiting growth and/or suppressing microbial respiration. The high photosynthetic light-use efficiency showed this site to be a highly productive boreal deciduous forest, with properties similar to many temperate deciduous forests. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
13541013
Volume :
13
Issue :
3
Database :
Complementary Index
Journal :
Global Change Biology
Publication Type :
Academic Journal
Accession number :
24410468
Full Text :
https://doi.org/10.1111/j.1365-2486.2006.01220.x