Effects of mutual shading of tree crowns on prediction of photosynthetic light-use efficiency in a coastal Douglas-fir forest
Effects of mutual shading of tree crowns on prediction of photosynthetic light-use efficiency in a coastal Douglas-fir forest
Gross primary production (GPP) is often expressed as the product of absorbed photosynthetically active radiation and the efficiency (epsilon) with which a plant community uses absorbed radiation in biomass production. Light-use efficiency is affected by environmental stresses, and varies diurnally and seasonally. Uncertainty about epsilon can be a serious limitation when modeling GPP. An important determinant of epsilon is the amount and type of solar radiation incident on a canopy, because an abundance of light can trigger a photo-protective reaction, diminishing GPP. The radiation regime in a forest canopy is determined by the predominant sky conditions and by mutual shading of tree crowns. Shading effects, producing shifts in the amount of incident direct and diffuse solar radiation, have been largely ignored, however, because they depend on forest structure and are difficult to measure. We describe a new approach for estimating changes in mutual canopy shading throughout the day and year based on a canopy structure model derived from light detection and ranging (LiDAR). Proportions of canopy shading were then combined with eddy covariance data to assess the explanatory power for variance in epsilon by regression tree analysis over half-hourly, daily and weekly time scales. The approach explained between 75 and 97{\%} of variance in epsilon, representing an increase of between 5 and 16{\%} compared with models driven solely by meteorological variables.
biological, canada, darkness, light, models, photosynthesis, photosynthesis physiology, pseudotsuga, pseudotsuga physiology, sunlight
825-834
Hilker, Thomas
c7fb75b8-320d-49df-84ba-96c9ee523d40
Coops, Nicholas C.
5511e778-fec2-4f54-8708-de65ba5a0992
Schwalm, Christopher R.
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Jassal, Rachhpal S.
f5bd97e1-42b3-412b-b4fd-a643ca9a6064
Black, T. Andrew
f6187e30-d043-4094-b5ef-372c60de403b
Krishnan, Praveena
279566d8-8be0-4b0b-bf46-4b447df3229d
June 2008
Hilker, Thomas
c7fb75b8-320d-49df-84ba-96c9ee523d40
Coops, Nicholas C.
5511e778-fec2-4f54-8708-de65ba5a0992
Schwalm, Christopher R.
751a2c45-fc76-465b-ac7e-e230d6bd191e
Jassal, Rachhpal S.
f5bd97e1-42b3-412b-b4fd-a643ca9a6064
Black, T. Andrew
f6187e30-d043-4094-b5ef-372c60de403b
Krishnan, Praveena
279566d8-8be0-4b0b-bf46-4b447df3229d
Hilker, Thomas, Coops, Nicholas C., Schwalm, Christopher R., Jassal, Rachhpal S., Black, T. Andrew and Krishnan, Praveena
(2008)
Effects of mutual shading of tree crowns on prediction of photosynthetic light-use efficiency in a coastal Douglas-fir forest.
Tree Physiology, 28 (6), .
(doi:10.1093/treephys/28.6.825).
(PMID:18381263)
Abstract
Gross primary production (GPP) is often expressed as the product of absorbed photosynthetically active radiation and the efficiency (epsilon) with which a plant community uses absorbed radiation in biomass production. Light-use efficiency is affected by environmental stresses, and varies diurnally and seasonally. Uncertainty about epsilon can be a serious limitation when modeling GPP. An important determinant of epsilon is the amount and type of solar radiation incident on a canopy, because an abundance of light can trigger a photo-protective reaction, diminishing GPP. The radiation regime in a forest canopy is determined by the predominant sky conditions and by mutual shading of tree crowns. Shading effects, producing shifts in the amount of incident direct and diffuse solar radiation, have been largely ignored, however, because they depend on forest structure and are difficult to measure. We describe a new approach for estimating changes in mutual canopy shading throughout the day and year based on a canopy structure model derived from light detection and ranging (LiDAR). Proportions of canopy shading were then combined with eddy covariance data to assess the explanatory power for variance in epsilon by regression tree analysis over half-hourly, daily and weekly time scales. The approach explained between 75 and 97{\%} of variance in epsilon, representing an increase of between 5 and 16{\%} compared with models driven solely by meteorological variables.
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Accepted/In Press date: 29 November 2007
e-pub ahead of print date: 1 April 2008
Published date: June 2008
Keywords:
biological, canada, darkness, light, models, photosynthesis, photosynthesis physiology, pseudotsuga, pseudotsuga physiology, sunlight
Organisations:
Earth Surface Dynamics
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Local EPrints ID: 384708
URI: http://eprints.soton.ac.uk/id/eprint/384708
ISSN: 0829-318X
PURE UUID: d641d972-4872-4328-adc4-e11ac443a4c8
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Date deposited: 18 Apr 2016 14:22
Last modified: 14 Mar 2024 22:03
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Contributors
Author:
Thomas Hilker
Author:
Nicholas C. Coops
Author:
Christopher R. Schwalm
Author:
Rachhpal S. Jassal
Author:
T. Andrew Black
Author:
Praveena Krishnan
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