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Assessing the impact of internal conductance to CO2 in a land-surface scheme: measurement and modelling of photosynthesis in Populus nigra

Assessing the impact of internal conductance to CO2 in a land-surface scheme: measurement and modelling of photosynthesis in Populus nigra
Assessing the impact of internal conductance to CO2 in a land-surface scheme: measurement and modelling of photosynthesis in Populus nigra
Vegetation plays a key role in both the global carbon and water cycles. Therefore, the representation of leaf-level fluxes of carbon and water in process-based land-surface schemes is central to accurately predicting these surface exchanges on a larger scale. Leaf-level models of photosynthesis used in such schemes are commonly based on the equations of Farquhar et al. (1980), which were founded on the assumption that differences in the drawdown of CO2 from sub-stomatal cavities (ci) to the site of carboxylation inside chloroplasts (cc) were negligible. Recent research, however, indicates an important role for this additional internal pathway of CO2 transfer (gi) in photosynthesis. This work therefore combined fieldwork and modelling to assess the impact of gi on estimation of key photosynthetic parameters, and on the accuracy of simulated photosynthesis (Anet) and stomatal conductance (gs) in a coupled model of leaf-level Anet and gs embedded in a land-surface scheme. It was shown that, in a fast growing poplar genotype (Populus nigra), the photosynthetic parameter Vmax was sensitive to gi. Determination of Vmax under the assumption of finite gi led to estimates of Vmax in well-watered trees that were, on average, 52% higher than values calculated on a ci basis. Drought induced declines in all key photosynthetic parameters measured were observed (Vmax, Jmax and gi), in addition to a two-fold increase in photosynthetic biochemical capacity upon re-watering. Reasons for this and the implications for land-surface modelling are discussed. It was shown that inclusion of a constant (non-water stressed) internal conductance to CO2 in a coupled model of leaf-level Anet and gs did not improve the accuracy of these simulated fluxes. It was concluded that, for application within a land-surface scheme, currently, accurate calibration of Vmax potentially has a greater impact on simulated Anet and gs than the inclusion of additional, fine-scale leaf-level processes such as gi
0168-1923
240-251
Oliver, Rebecca J.
d5dd1746-a92a-4b2c-89a7-76a4d818c9bb
Taylor, Gail
Finch, John W.
c49283f3-0594-4a34-95e2-5409e12ad7c3
Oliver, Rebecca J.
d5dd1746-a92a-4b2c-89a7-76a4d818c9bb
Taylor, Gail
Finch, John W.
c49283f3-0594-4a34-95e2-5409e12ad7c3

Oliver, Rebecca J., Taylor, Gail and Finch, John W. (2012) Assessing the impact of internal conductance to CO2 in a land-surface scheme: measurement and modelling of photosynthesis in Populus nigra. Agricultural and Forest Meteorology, 152, 240-251. (doi:10.1016/j.agrformet.2011.10.001).

Record type: Article

Abstract

Vegetation plays a key role in both the global carbon and water cycles. Therefore, the representation of leaf-level fluxes of carbon and water in process-based land-surface schemes is central to accurately predicting these surface exchanges on a larger scale. Leaf-level models of photosynthesis used in such schemes are commonly based on the equations of Farquhar et al. (1980), which were founded on the assumption that differences in the drawdown of CO2 from sub-stomatal cavities (ci) to the site of carboxylation inside chloroplasts (cc) were negligible. Recent research, however, indicates an important role for this additional internal pathway of CO2 transfer (gi) in photosynthesis. This work therefore combined fieldwork and modelling to assess the impact of gi on estimation of key photosynthetic parameters, and on the accuracy of simulated photosynthesis (Anet) and stomatal conductance (gs) in a coupled model of leaf-level Anet and gs embedded in a land-surface scheme. It was shown that, in a fast growing poplar genotype (Populus nigra), the photosynthetic parameter Vmax was sensitive to gi. Determination of Vmax under the assumption of finite gi led to estimates of Vmax in well-watered trees that were, on average, 52% higher than values calculated on a ci basis. Drought induced declines in all key photosynthetic parameters measured were observed (Vmax, Jmax and gi), in addition to a two-fold increase in photosynthetic biochemical capacity upon re-watering. Reasons for this and the implications for land-surface modelling are discussed. It was shown that inclusion of a constant (non-water stressed) internal conductance to CO2 in a coupled model of leaf-level Anet and gs did not improve the accuracy of these simulated fluxes. It was concluded that, for application within a land-surface scheme, currently, accurate calibration of Vmax potentially has a greater impact on simulated Anet and gs than the inclusion of additional, fine-scale leaf-level processes such as gi

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e-pub ahead of print date: 4 November 2011
Published date: 15 January 2012
Organisations: Centre for Biological Sciences

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Local EPrints ID: 210976
URI: http://eprints.soton.ac.uk/id/eprint/210976
ISSN: 0168-1923
PURE UUID: 00d78b0f-5a8c-481e-83cf-25913a4403bb

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Date deposited: 17 Feb 2012 11:04
Last modified: 14 Mar 2024 04:51

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Contributors

Author: Rebecca J. Oliver
Author: Gail Taylor
Author: John W. Finch

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