Modeling the impacts of diffuse light fraction on photosynthesis in ORCHIDEE (v5453) land surface model

Yuan Zhang; Ana Bastos; Fabienne Maignan; Daniel Goll; Olivier Boucher; Laurent Li; Alessandro Cescatti; Nicolas Vuichard; Xiuzhi Chen; Christof Ammann; M. Altaf Arain; T. Andrew Black; Bogdan Chojnicki; Tomomichi Kato; Ivan Mammarella; Leonardo Montagnani; Olivier Roupsard; Maria J. Sanz; Lukas Siebicke; Marek Urbaniak; Francesco Primo Vaccari; Georg Wohlfahrt; Will Woodgate; Philippe Ciais

doi:10.5194/gmd-13-5401-2020

Modeling the impacts of diffuse light fraction on photosynthesis in ORCHIDEE (v5453) land surface model

Yuan Zhang
, Ana Bastos
, Fabienne Maignan
, Daniel Goll
, Olivier Boucher
, Laurent Li
, Alessandro Cescatti
, Nicolas Vuichard
, Xiuzhi Chen
, Christof Ammann
, M. Altaf Arain
, T. Andrew Black
, Bogdan Chojnicki
, Tomomichi Kato
, Ivan Mammarella
, Leonardo Montagnani
, Olivier Roupsard
, Maria J. Sanz
, Lukas Siebicke
, Marek Urbaniak

Francesco Primo Vaccari, Georg Wohlfahrt, Will Woodgate, Philippe Ciais

Sorbonne Université
Université Versailles-Saint Quentin
Max Planck Institute for Biogeochemistry
University of Augsburg
European Commission Joint Research Centre
Sun Yat-Sen University
Agroscope
McMaster Centre For Climate Change
University of British Columbia
Poznań University of Life Sciences
Hokkaido University
University of Helsinki
Forest Services
Free University of Bozen-Bolzano
Campus International de Baillarguet
Université de Montpellier
Institut de Recherche pour le Développement Dakar
Basque Centre for Climate Change (BC3)
CIBERfes
Georg-August-Universität Göttingen
Ev-K2-CNR Committee
University of Innsbruck
Commonwealth Scientific and Industrial Research Organization
University of Queensland

Research output: Contribution to journal › Article › peer-review

Abstract

Aerosol- and cloud-induced changes in diffuse light have important impacts on the global land carbon cycle, as they alter light distribution and photosynthesis in vegetation canopies. However, this effect remains poorly represented or evaluated in current land surface models. Here, we add a light partitioning module and a new canopy light transmission module to the ORCHIDEE (Organising Carbon and Hydrology In Dynamic Ecosystems) land surface model (trunk version, v5453) and use the revised model, ORCHIDEE- DF, to estimate the fraction of diffuse light and its effect on gross primary production (GPP) in a multilayer canopy. We evaluate the new parameterizations using flux observations from 159 eddy covariance sites over the globe. Our results show that, compared with the original model, ORCHIDEE-DF improves the GPP simulation under sunny conditions and captures the observed higher photosynthesis under cloudier conditions in most plant functional types (PFTs). Our results also indicate that the larger GPP under cloudy conditions compared with sunny conditions is mainly driven by increased diffuse light in the morning and in the afternoon as well as by a decreased vapor pressure deficit (VPD) and decreased air temperature at midday. The observations show that the strongest positive effects of diffuse light on photosynthesis are found in the range from 5 to 20 °C and at a VPD< 1 kPa. This effect is found to decrease when the VPD becomes too large or the temperature falls outside of the abovementioned range, which is likely due to the increasing stomatal resistance to leaf CO2 uptake. ORCHIDEE-DF underestimates the diffuse light effect at low temperature in all PFTs and overestimates this effect at high temperature and at a high VPD in grasslands and croplands. The new model has the potential to better investigate the impact of large-scale aerosol changes and long-term changes in cloudiness on the terrestrial carbon budget, both in the historical period and in the context of future air quality policies and/or climate engineering.

Original language	English
Article number	5401-2020
Pages (from-to)	5401-5423
Number of pages	23
Journal	Geoscientific Model Development
Volume	13
Issue number	11
DOIs	https://doi.org/10.5194/gmd-13-5401-2020
Publication status	Published - 10 Nov 2020

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 13 Climate Action
SDG 15 Life on Land

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10.5194/gmd-13-5401-2020

Cite this

Zhang, Y., Bastos, A., Maignan, F., Goll, D., Boucher, O., Li, L., Cescatti, A., Vuichard, N., Chen, X., Ammann, C., Altaf Arain, M., Andrew Black, T., Chojnicki, B., Kato, T., Mammarella, I., Montagnani, L., Roupsard, O., Sanz, M. J., Siebicke, L., ... Ciais, P. (2020). Modeling the impacts of diffuse light fraction on photosynthesis in ORCHIDEE (v5453) land surface model. Geoscientific Model Development, 13(11), 5401-5423. Article 5401-2020. https://doi.org/10.5194/gmd-13-5401-2020

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title = "Modeling the impacts of diffuse light fraction on photosynthesis in ORCHIDEE (v5453) land surface model",

abstract = "Aerosol- and cloud-induced changes in diffuse light have important impacts on the global land carbon cycle, as they alter light distribution and photosynthesis in vegetation canopies. However, this effect remains poorly represented or evaluated in current land surface models. Here, we add a light partitioning module and a new canopy light transmission module to the ORCHIDEE (Organising Carbon and Hydrology In Dynamic Ecosystems) land surface model (trunk version, v5453) and use the revised model, ORCHIDEE- DF, to estimate the fraction of diffuse light and its effect on gross primary production (GPP) in a multilayer canopy. We evaluate the new parameterizations using flux observations from 159 eddy covariance sites over the globe. Our results show that, compared with the original model, ORCHIDEE-DF improves the GPP simulation under sunny conditions and captures the observed higher photosynthesis under cloudier conditions in most plant functional types (PFTs). Our results also indicate that the larger GPP under cloudy conditions compared with sunny conditions is mainly driven by increased diffuse light in the morning and in the afternoon as well as by a decreased vapor pressure deficit (VPD) and decreased air temperature at midday. The observations show that the strongest positive effects of diffuse light on photosynthesis are found in the range from 5 to 20 °C and at a VPD< 1 kPa. This effect is found to decrease when the VPD becomes too large or the temperature falls outside of the abovementioned range, which is likely due to the increasing stomatal resistance to leaf CO2 uptake. ORCHIDEE-DF underestimates the diffuse light effect at low temperature in all PFTs and overestimates this effect at high temperature and at a high VPD in grasslands and croplands. The new model has the potential to better investigate the impact of large-scale aerosol changes and long-term changes in cloudiness on the terrestrial carbon budget, both in the historical period and in the context of future air quality policies and/or climate engineering.",

author = "Yuan Zhang and Ana Bastos and Fabienne Maignan and Daniel Goll and Olivier Boucher and Laurent Li and Alessandro Cescatti and Nicolas Vuichard and Xiuzhi Chen and Christof Ammann and \{Altaf Arain\}, M. and \{Andrew Black\}, T. and Bogdan Chojnicki and Tomomichi Kato and Ivan Mammarella and Leonardo Montagnani and Olivier Roupsard and Sanz, \{Maria J.\} and Lukas Siebicke and Marek Urbaniak and \{Primo Vaccari\}, Francesco and Georg Wohlfahrt and Will Woodgate and Philippe Ciais",

note = "Publisher Copyright: {\textcopyright} Author(s) 2020.",

year = "2020",

month = nov,

day = "10",

doi = "10.5194/gmd-13-5401-2020",

language = "English",

volume = "13",

pages = "5401--5423",

journal = "Geoscientific Model Development",

issn = "1991-959X",

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Zhang, Y, Bastos, A, Maignan, F, Goll, D, Boucher, O, Li, L, Cescatti, A, Vuichard, N, Chen, X, Ammann, C, Altaf Arain, M, Andrew Black, T, Chojnicki, B, Kato, T, Mammarella, I, Montagnani, L, Roupsard, O, Sanz, MJ, Siebicke, L, Urbaniak, M, Primo Vaccari, F, Wohlfahrt, G, Woodgate, W & Ciais, P 2020, 'Modeling the impacts of diffuse light fraction on photosynthesis in ORCHIDEE (v5453) land surface model', Geoscientific Model Development, vol. 13, no. 11, 5401-2020, pp. 5401-5423. https://doi.org/10.5194/gmd-13-5401-2020

TY - JOUR

T1 - Modeling the impacts of diffuse light fraction on photosynthesis in ORCHIDEE (v5453) land surface model

AU - Zhang, Yuan

AU - Bastos, Ana

AU - Maignan, Fabienne

AU - Goll, Daniel

AU - Boucher, Olivier

AU - Li, Laurent

AU - Cescatti, Alessandro

AU - Vuichard, Nicolas

AU - Chen, Xiuzhi

AU - Ammann, Christof

AU - Altaf Arain, M.

AU - Andrew Black, T.

AU - Chojnicki, Bogdan

AU - Kato, Tomomichi

AU - Mammarella, Ivan

AU - Montagnani, Leonardo

AU - Roupsard, Olivier

AU - Sanz, Maria J.

AU - Siebicke, Lukas

AU - Urbaniak, Marek

AU - Primo Vaccari, Francesco

AU - Wohlfahrt, Georg

AU - Woodgate, Will

AU - Ciais, Philippe

PY - 2020/11/10

Y1 - 2020/11/10

N2 - Aerosol- and cloud-induced changes in diffuse light have important impacts on the global land carbon cycle, as they alter light distribution and photosynthesis in vegetation canopies. However, this effect remains poorly represented or evaluated in current land surface models. Here, we add a light partitioning module and a new canopy light transmission module to the ORCHIDEE (Organising Carbon and Hydrology In Dynamic Ecosystems) land surface model (trunk version, v5453) and use the revised model, ORCHIDEE- DF, to estimate the fraction of diffuse light and its effect on gross primary production (GPP) in a multilayer canopy. We evaluate the new parameterizations using flux observations from 159 eddy covariance sites over the globe. Our results show that, compared with the original model, ORCHIDEE-DF improves the GPP simulation under sunny conditions and captures the observed higher photosynthesis under cloudier conditions in most plant functional types (PFTs). Our results also indicate that the larger GPP under cloudy conditions compared with sunny conditions is mainly driven by increased diffuse light in the morning and in the afternoon as well as by a decreased vapor pressure deficit (VPD) and decreased air temperature at midday. The observations show that the strongest positive effects of diffuse light on photosynthesis are found in the range from 5 to 20 °C and at a VPD< 1 kPa. This effect is found to decrease when the VPD becomes too large or the temperature falls outside of the abovementioned range, which is likely due to the increasing stomatal resistance to leaf CO2 uptake. ORCHIDEE-DF underestimates the diffuse light effect at low temperature in all PFTs and overestimates this effect at high temperature and at a high VPD in grasslands and croplands. The new model has the potential to better investigate the impact of large-scale aerosol changes and long-term changes in cloudiness on the terrestrial carbon budget, both in the historical period and in the context of future air quality policies and/or climate engineering.

AB - Aerosol- and cloud-induced changes in diffuse light have important impacts on the global land carbon cycle, as they alter light distribution and photosynthesis in vegetation canopies. However, this effect remains poorly represented or evaluated in current land surface models. Here, we add a light partitioning module and a new canopy light transmission module to the ORCHIDEE (Organising Carbon and Hydrology In Dynamic Ecosystems) land surface model (trunk version, v5453) and use the revised model, ORCHIDEE- DF, to estimate the fraction of diffuse light and its effect on gross primary production (GPP) in a multilayer canopy. We evaluate the new parameterizations using flux observations from 159 eddy covariance sites over the globe. Our results show that, compared with the original model, ORCHIDEE-DF improves the GPP simulation under sunny conditions and captures the observed higher photosynthesis under cloudier conditions in most plant functional types (PFTs). Our results also indicate that the larger GPP under cloudy conditions compared with sunny conditions is mainly driven by increased diffuse light in the morning and in the afternoon as well as by a decreased vapor pressure deficit (VPD) and decreased air temperature at midday. The observations show that the strongest positive effects of diffuse light on photosynthesis are found in the range from 5 to 20 °C and at a VPD< 1 kPa. This effect is found to decrease when the VPD becomes too large or the temperature falls outside of the abovementioned range, which is likely due to the increasing stomatal resistance to leaf CO2 uptake. ORCHIDEE-DF underestimates the diffuse light effect at low temperature in all PFTs and overestimates this effect at high temperature and at a high VPD in grasslands and croplands. The new model has the potential to better investigate the impact of large-scale aerosol changes and long-term changes in cloudiness on the terrestrial carbon budget, both in the historical period and in the context of future air quality policies and/or climate engineering.

UR - https://www.scopus.com/pages/publications/85096070068

U2 - 10.5194/gmd-13-5401-2020

DO - 10.5194/gmd-13-5401-2020

M3 - Article

AN - SCOPUS:85096070068

SN - 1991-959X

VL - 13

SP - 5401

EP - 5423

JO - Geoscientific Model Development

JF - Geoscientific Model Development

IS - 11

M1 - 5401-2020

ER -

Modeling the impacts of diffuse light fraction on photosynthesis in ORCHIDEE (v5453) land surface model

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