P-model v1.0: An optimality-based light use efficiency model for simulating ecosystem gross primary production

Benjamin D. Stocker; Han Wang; Nicholas Smith; Sandy P. Harrison; Trevor F. Keenan; David Sandoval; Tyler Davis; I. Colin Prentice

doi:10.5194/gmd-2019-200

P-model v1.0: An optimality-based light use efficiency model for simulating ecosystem gross primary production

Benjamin D. Stocker, Han Wang, Nicholas Smith, Sandy P. Harrison, Trevor F. Keenan, David Sandoval, Tyler Davis, I. Colin Prentice

Biological Sciences

Research output: Other contribution

Abstract

Abstract. Terrestrial photosynthesis is the basis for vegetation growth and drives the land carbon cycle. Accurately simulating gross primary production (GPP, ecosystem-level apparent photosynthesis) is key for satellite monitoring and Earth System Model predictions under climate change. While robust models exist for describing leaf-level photosynthesis, predictions diverge due to uncertain photosynthetic traits and parameters which vary on multiple spatial and temporal scales. Here, we describe and evaluate a gross primary production (GPP, photosynthesis per unit ground area) model, the P-model, that combines the Farquhar-von Caemmerer-Berry model for C3 photosynthesis with an optimality principle for the carbon assimilation-transpiration trade-off, and predicts a multi-day average light use efficiency (LUE) for any climate and C3 vegetation type. The model is forced here with satellite data for the fraction of absorbed photosynthetically active radiation and site-specific me

Original language	English
Publisher	Copernicus GmbH
DOIs	https://doi.org/10.5194/gmd-2019-200
State	Published - 2019

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@misc{f54cb003085e47f8bc5e60a7dbf1cc01,

title = "P-model v1.0: An optimality-based light use efficiency model for simulating ecosystem gross primary production",

abstract = "Abstract. Terrestrial photosynthesis is the basis for vegetation growth and drives the land carbon cycle. Accurately simulating gross primary production (GPP, ecosystem-level apparent photosynthesis) is key for satellite monitoring and Earth System Model predictions under climate change. While robust models exist for describing leaf-level photosynthesis, predictions diverge due to uncertain photosynthetic traits and parameters which vary on multiple spatial and temporal scales. Here, we describe and evaluate a gross primary production (GPP, photosynthesis per unit ground area) model, the P-model, that combines the Farquhar-von Caemmerer-Berry model for C3 photosynthesis with an optimality principle for the carbon assimilation-transpiration trade-off, and predicts a multi-day average light use efficiency (LUE) for any climate and C3 vegetation type. The model is forced here with satellite data for the fraction of absorbed photosynthetically active radiation and site-specific me",

author = "Stocker, {Benjamin D.} and Han Wang and Nicholas Smith and Harrison, {Sandy P.} and Keenan, {Trevor F.} and David Sandoval and Tyler Davis and Prentice, {I. Colin}",

year = "2019",

doi = "10.5194/gmd-2019-200",

language = "English",

publisher = "Copernicus GmbH",

type = "Other",

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TY - GEN

T1 - P-model v1.0: An optimality-based light use efficiency model for simulating ecosystem gross primary production

AU - Stocker, Benjamin D.

AU - Wang, Han

AU - Smith, Nicholas

AU - Harrison, Sandy P.

AU - Keenan, Trevor F.

AU - Sandoval, David

AU - Davis, Tyler

AU - Prentice, I. Colin

PY - 2019

Y1 - 2019

N2 - Abstract. Terrestrial photosynthesis is the basis for vegetation growth and drives the land carbon cycle. Accurately simulating gross primary production (GPP, ecosystem-level apparent photosynthesis) is key for satellite monitoring and Earth System Model predictions under climate change. While robust models exist for describing leaf-level photosynthesis, predictions diverge due to uncertain photosynthetic traits and parameters which vary on multiple spatial and temporal scales. Here, we describe and evaluate a gross primary production (GPP, photosynthesis per unit ground area) model, the P-model, that combines the Farquhar-von Caemmerer-Berry model for C3 photosynthesis with an optimality principle for the carbon assimilation-transpiration trade-off, and predicts a multi-day average light use efficiency (LUE) for any climate and C3 vegetation type. The model is forced here with satellite data for the fraction of absorbed photosynthetically active radiation and site-specific me

AB - Abstract. Terrestrial photosynthesis is the basis for vegetation growth and drives the land carbon cycle. Accurately simulating gross primary production (GPP, ecosystem-level apparent photosynthesis) is key for satellite monitoring and Earth System Model predictions under climate change. While robust models exist for describing leaf-level photosynthesis, predictions diverge due to uncertain photosynthetic traits and parameters which vary on multiple spatial and temporal scales. Here, we describe and evaluate a gross primary production (GPP, photosynthesis per unit ground area) model, the P-model, that combines the Farquhar-von Caemmerer-Berry model for C3 photosynthesis with an optimality principle for the carbon assimilation-transpiration trade-off, and predicts a multi-day average light use efficiency (LUE) for any climate and C3 vegetation type. The model is forced here with satellite data for the fraction of absorbed photosynthetically active radiation and site-specific me

U2 - 10.5194/gmd-2019-200

DO - 10.5194/gmd-2019-200

M3 - Other contribution

PB - Copernicus GmbH

ER -