Why is plant-growth response to elevated CO2 amplified when water is limiting but reduced when nitrogen is limiting? A growth-optimisation hypothesis.

McMurtrie, Ross E; Norby, Richard J; Ellsworth, David; Tissue, David Thomas

doi:10.1071/FP08128

Title: Why is plant-growth response to elevated CO2 amplified when water is limiting but reduced when nitrogen is limiting? A growth-optimisation hypothesis.

Journal Article · Tue Jan 01 00:00:00 EST 2008 · Functional Plant Biology

DOI:https://doi.org/10.1071/FP08128· OSTI ID:936284

McMurtrie, Ross E ^[1]; Norby, Richard J ^[1]; Ellsworth, David ^[1]; Tissue, David Thomas ^[1]

ORNL

Considerable experimental evidence indicates that stomatal conductance and leaf-nitrogen concentration ([N]) decline under CO2-enrichment, and that the percentage growth response of plants to elevated CO2 is amplified under water limitation but reduced under nitrogen limitation. In this paper we advance simple explanations for these responses based on an optimisation hypothesis. We explore this hypothesis using a simple model of the annual carbon - nitrogen - water economy of deciduous trees growing at a ten-year duration CO2-enrichment field experiment at Oak Ridge, Tennessee. The model is shown to have an optimum for leaf [N], stomatal conductance and leaf-area index (LAI), where annual plant productivity is maximised. The model is used to evaluate the optimum in years with contrasting rainfall and N fertility. If annual rainfall is increased, the optimum shifts to increased stomatal conductance and LAI and reduced leaf [N], whereas if N supply is increased, the optimum shifts to increased leaf [N] and LAI and reduced stomatal conductance. When atmospheric CO2 concentration ([CO2]) is increased, the optimum shifts to reduced stomatal conductance and leaf [N] and enhanced LAI. The model is used to predict maximum net primary productivity (NPP) at current and elevated [CO2] in years with contrasting rainfall and plant N uptake. The predicted CO2 response of maximum NPP is greatest in a dry, high-N year and least in a wet, low-N year. The underlying physiological explanation for this contrast in the effects of water versus nitrogen limitation is that leaf photosynthesis is more sensitive to [CO2] at lower stomatal conductance whereas it is less sensitive to [CO2] at lower leaf [N].

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Research Organization:: Oak Ridge National Lab. (ORNL), Oak Ridge, TN (United States). Oak Ridge National Environmental Research Park

Sponsoring Organization:: USDOE Office of Science (SC)

DOE Contract Number:: DE-AC05-00OR22725

OSTI ID:: 936284

Journal Information:: Functional Plant Biology, Vol. 35, Issue 6; ISSN 1445-4408

Country of Publication:: United States

Language:: English

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Title: Why is plant-growth response to elevated CO2 amplified when water is limiting but reduced when nitrogen is limiting? A growth-optimisation hypothesis.

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