Addressing Challenges in Simulating Inter–Annual Variability of Gross Primary Production

Ranit De; Shanning Bao; Sujan Koirala; Alexander Brenning; Markus Reichstein; Torbern Tagesson; Michael Liddell; Andreas Ibrom; Sebastian Wolf; Ladislav Šigut; Lukas Hörtnagl; William Woodgate; Mika Korkiakoski; Lutz Merbold; T. Andrew Black; Marilyn Roland; Anne Klosterhalfen; Peter D. Blanken; Sara Knox; Simone Sabbatini; Bert Gielen; Leonardo Montagnani; Rasmus Fensholt; Georg Wohlfahrt; Ankur R. Desai; Eugénie Paul-Limoges; Marta Galvagno; Albin Hammerle; Georg Jocher; Borja Ruiz Reverter; David Holl; Jiquan Chen; Luca Vitale; M. Altaf Arain; Nuno Carvalhais

doi:10.1029/2024MS004697

Addressing Challenges in Simulating Inter–Annual Variability of Gross Primary Production

Ranit De^*, Shanning Bao^*, Sujan Koirala, Alexander Brenning, Markus Reichstein, Torbern Tagesson, Michael Liddell, Andreas Ibrom, Sebastian Wolf, Ladislav Šigut, Lukas Hörtnagl, William Woodgate, Mika Korkiakoski, Lutz Merbold, T. Andrew Black, Marilyn Roland, Anne Klosterhalfen, Peter D. Blanken, Sara Knox, Simone SabbatiniBert Gielen, Leonardo Montagnani, Rasmus Fensholt, Georg Wohlfahrt, Ankur R. Desai, Eugénie Paul-Limoges, Marta Galvagno, Albin Hammerle, Georg Jocher, Borja Ruiz Reverter, David Holl, Jiquan Chen, Luca Vitale, M. Altaf Arain, Nuno Carvalhais^*

^*Corresponding author for this work

Geography, Land, Environment and Society

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Abstract

A long-standing challenge in studying the global carbon cycle has been understanding the factors controlling inter–annual variation (IAV) of carbon fluxes, and improving their representations in existing biogeochemical models. Here, we compared an optimality-based model and a semi-empirical light use efficiency model to understand how current models can be improved to simulate IAV of gross primary production (GPP). Both models simulated hourly GPP and were parameterized for (a) each site–year, (b) each site with an additional constraint on IAV ((Formula presented.)), (c) each site, (d) each plant–functional type, and (e) globally. This was followed by forward runs using calibrated parameters, and model evaluations using Nash–Sutcliffe efficiency (NSE) as a model-fitness measure at different temporal scales across 198 eddy-covariance sites representing diverse climate–vegetation types. Both models simulated hourly GPP better (median normalized NSE: 0.83 and 0.85) than annual GPP (median normalized NSE: 0.54 and 0.63) for most sites. Specifically, the optimality-based model substantially improved from NSE of −1.39 to 0.92 when drought stress was explicitly included. Most of the variability in model performances was due to model types and parameterization strategies. The semi-empirical model produced statistically better hourly simulations than the optimality-based model, and site–year parameterization yielded better annual model performance. Annual model performance did not improve even when parameterized using (Formula presented.). Furthermore, both models underestimated the peaks of diurnal GPP, suggesting that improving predictions of peaks could produce better annual model performance. Our findings reveal current modeling deficiencies in representing IAV of carbon fluxes and guide improvements in further model development.

Original language	English
Article number	e2024MS004697
Journal	Journal of Advances in Modeling Earth Systems
Volume	17
Issue number	5
Number of pages	44
ISSN	1942-2466
DOIs	https://doi.org/10.1029/2024MS004697
Publication status	Published - 2025

Bibliographical note

Publisher Copyright:
© 2025 The Author(s). Journal of Advances in Modeling Earth Systems published by Wiley Periodicals LLC on behalf of American Geophysical Union.

Keywords

carbon flux
eddy covariance
gross primary production
inter–annual variability
light use efficiency
optimality-based model

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Cite this

De, R., Bao, S., Koirala, S., Brenning, A., Reichstein, M., Tagesson, T., Liddell, M., Ibrom, A., Wolf, S., Šigut, L., Hörtnagl, L., Woodgate, W., Korkiakoski, M., Merbold, L., Black, T. A., Roland, M., Klosterhalfen, A., Blanken, P. D., Knox, S., ... Carvalhais, N. (2025). Addressing Challenges in Simulating Inter–Annual Variability of Gross Primary Production. Journal of Advances in Modeling Earth Systems, 17(5), Article e2024MS004697. https://doi.org/10.1029/2024MS004697

De, R, Bao, S, Koirala, S, Brenning, A, Reichstein, M, Tagesson, T, Liddell, M, Ibrom, A, Wolf, S, Šigut, L, Hörtnagl, L, Woodgate, W, Korkiakoski, M, Merbold, L, Black, TA, Roland, M, Klosterhalfen, A, Blanken, PD, Knox, S, Sabbatini, S, Gielen, B, Montagnani, L, Fensholt, R, Wohlfahrt, G, Desai, AR, Paul-Limoges, E, Galvagno, M, Hammerle, A, Jocher, G, Reverter, BR, Holl, D, Chen, J, Vitale, L, Arain, MA & Carvalhais, N 2025, 'Addressing Challenges in Simulating Inter–Annual Variability of Gross Primary Production', Journal of Advances in Modeling Earth Systems, vol. 17, no. 5, e2024MS004697. https://doi.org/10.1029/2024MS004697

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abstract = "A long-standing challenge in studying the global carbon cycle has been understanding the factors controlling inter–annual variation (IAV) of carbon fluxes, and improving their representations in existing biogeochemical models. Here, we compared an optimality-based model and a semi-empirical light use efficiency model to understand how current models can be improved to simulate IAV of gross primary production (GPP). Both models simulated hourly GPP and were parameterized for (a) each site–year, (b) each site with an additional constraint on IAV ((Formula presented.)), (c) each site, (d) each plant–functional type, and (e) globally. This was followed by forward runs using calibrated parameters, and model evaluations using Nash–Sutcliffe efficiency (NSE) as a model-fitness measure at different temporal scales across 198 eddy-covariance sites representing diverse climate–vegetation types. Both models simulated hourly GPP better (median normalized NSE: 0.83 and 0.85) than annual GPP (median normalized NSE: 0.54 and 0.63) for most sites. Specifically, the optimality-based model substantially improved from NSE of −1.39 to 0.92 when drought stress was explicitly included. Most of the variability in model performances was due to model types and parameterization strategies. The semi-empirical model produced statistically better hourly simulations than the optimality-based model, and site–year parameterization yielded better annual model performance. Annual model performance did not improve even when parameterized using (Formula presented.). Furthermore, both models underestimated the peaks of diurnal GPP, suggesting that improving predictions of peaks could produce better annual model performance. Our findings reveal current modeling deficiencies in representing IAV of carbon fluxes and guide improvements in further model development.",

keywords = "carbon flux, eddy covariance, gross primary production, inter–annual variability, light use efficiency, optimality-based model",

author = "Ranit De and Shanning Bao and Sujan Koirala and Alexander Brenning and Markus Reichstein and Torbern Tagesson and Michael Liddell and Andreas Ibrom and Sebastian Wolf and Ladislav {\v S}igut and Lukas H{\"o}rtnagl and William Woodgate and Mika Korkiakoski and Lutz Merbold and Black, {T. Andrew} and Marilyn Roland and Anne Klosterhalfen and Blanken, {Peter D.} and Sara Knox and Simone Sabbatini and Bert Gielen and Leonardo Montagnani and Rasmus Fensholt and Georg Wohlfahrt and Desai, {Ankur R.} and Eug{\'e}nie Paul-Limoges and Marta Galvagno and Albin Hammerle and Georg Jocher and Reverter, {Borja Ruiz} and David Holl and Jiquan Chen and Luca Vitale and Arain, {M. Altaf} and Nuno Carvalhais",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Journal of Advances in Modeling Earth Systems published by Wiley Periodicals LLC on behalf of American Geophysical Union.",

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AU - Bao, Shanning

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AU - Reichstein, Markus

AU - Tagesson, Torbern

AU - Liddell, Michael

AU - Ibrom, Andreas

AU - Wolf, Sebastian

AU - Šigut, Ladislav

AU - Hörtnagl, Lukas

AU - Woodgate, William

AU - Korkiakoski, Mika

AU - Merbold, Lutz

AU - Black, T. Andrew

AU - Roland, Marilyn

AU - Klosterhalfen, Anne

AU - Blanken, Peter D.

AU - Knox, Sara

AU - Sabbatini, Simone

AU - Gielen, Bert

AU - Montagnani, Leonardo

AU - Fensholt, Rasmus

AU - Wohlfahrt, Georg

AU - Desai, Ankur R.

AU - Paul-Limoges, Eugénie

AU - Galvagno, Marta

AU - Hammerle, Albin

AU - Jocher, Georg

AU - Reverter, Borja Ruiz

AU - Holl, David

AU - Chen, Jiquan

AU - Vitale, Luca

AU - Arain, M. Altaf

AU - Carvalhais, Nuno

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N2 - A long-standing challenge in studying the global carbon cycle has been understanding the factors controlling inter–annual variation (IAV) of carbon fluxes, and improving their representations in existing biogeochemical models. Here, we compared an optimality-based model and a semi-empirical light use efficiency model to understand how current models can be improved to simulate IAV of gross primary production (GPP). Both models simulated hourly GPP and were parameterized for (a) each site–year, (b) each site with an additional constraint on IAV ((Formula presented.)), (c) each site, (d) each plant–functional type, and (e) globally. This was followed by forward runs using calibrated parameters, and model evaluations using Nash–Sutcliffe efficiency (NSE) as a model-fitness measure at different temporal scales across 198 eddy-covariance sites representing diverse climate–vegetation types. Both models simulated hourly GPP better (median normalized NSE: 0.83 and 0.85) than annual GPP (median normalized NSE: 0.54 and 0.63) for most sites. Specifically, the optimality-based model substantially improved from NSE of −1.39 to 0.92 when drought stress was explicitly included. Most of the variability in model performances was due to model types and parameterization strategies. The semi-empirical model produced statistically better hourly simulations than the optimality-based model, and site–year parameterization yielded better annual model performance. Annual model performance did not improve even when parameterized using (Formula presented.). Furthermore, both models underestimated the peaks of diurnal GPP, suggesting that improving predictions of peaks could produce better annual model performance. Our findings reveal current modeling deficiencies in representing IAV of carbon fluxes and guide improvements in further model development.

AB - A long-standing challenge in studying the global carbon cycle has been understanding the factors controlling inter–annual variation (IAV) of carbon fluxes, and improving their representations in existing biogeochemical models. Here, we compared an optimality-based model and a semi-empirical light use efficiency model to understand how current models can be improved to simulate IAV of gross primary production (GPP). Both models simulated hourly GPP and were parameterized for (a) each site–year, (b) each site with an additional constraint on IAV ((Formula presented.)), (c) each site, (d) each plant–functional type, and (e) globally. This was followed by forward runs using calibrated parameters, and model evaluations using Nash–Sutcliffe efficiency (NSE) as a model-fitness measure at different temporal scales across 198 eddy-covariance sites representing diverse climate–vegetation types. Both models simulated hourly GPP better (median normalized NSE: 0.83 and 0.85) than annual GPP (median normalized NSE: 0.54 and 0.63) for most sites. Specifically, the optimality-based model substantially improved from NSE of −1.39 to 0.92 when drought stress was explicitly included. Most of the variability in model performances was due to model types and parameterization strategies. The semi-empirical model produced statistically better hourly simulations than the optimality-based model, and site–year parameterization yielded better annual model performance. Annual model performance did not improve even when parameterized using (Formula presented.). Furthermore, both models underestimated the peaks of diurnal GPP, suggesting that improving predictions of peaks could produce better annual model performance. Our findings reveal current modeling deficiencies in representing IAV of carbon fluxes and guide improvements in further model development.

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KW - eddy covariance

KW - gross primary production

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KW - light use efficiency

KW - optimality-based model

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DO - 10.1029/2024MS004697

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