Increasing Functional Diversity in a Global Land Surface Model Illustrates Uncertainties Related to Parameter Simplification

Ethan E. Butler; Kirk R. Wythers; Habacuc Flores-Moreno; Daniel M. Ricciuto; Abhirup Datta; Arindam Banerjee; Owen K. Atkin; Jens Kattge; Peter E. Thornton; Madhur Anand; Sabina Burrascano; Chaeho Byun; J. H.C. Cornelissen; Estelle Forey; Steven Jansen; Koen Kramer; Vanessa Minden; Peter B. Reich

doi:10.1029/2021JG006606

Increasing Functional Diversity in a Global Land Surface Model Illustrates Uncertainties Related to Parameter Simplification

Ethan E. Butler, Kirk R. Wythers, Habacuc Flores-Moreno, Daniel M. Ricciuto, Abhirup Datta, Arindam Banerjee, Owen K. Atkin, Jens Kattge, Peter E. Thornton, Madhur Anand, Sabina Burrascano, Chaeho Byun, J. H.C. Cornelissen, Estelle Forey, Steven Jansen, Koen Kramer, Vanessa Minden, Peter B. Reich

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

8 Scopus citations

Abstract

Simulations of the land surface carbon cycle typically compress functional diversity into a small set of plant functional types (PFT), with parameters defined by the average value of measurements of functional traits. In most earth system models, all wild plant life is represented by between five and 14 PFTs and a typical grid cell (≈100 × 100 km) may contain a single PFT. Model logic applied to this coarse representation of ecological functional diversity provides a reasonable proxy for the carbon cycle, but does not capture the non-linear influence of functional traits on productivity. Here we show through simulations using the Energy Exascale Land Surface Model in 15 diverse terrestrial landscapes, that better accounting for functional diversity markedly alters predicted total carbon uptake. The shift in carbon uptake is as great as 30% and 10% in boreal and tropical regions, respectively, when compared to a single PFT parameterized with the trait means. The traits that best predict gross primary production vary based on vegetation phenology, which broadly determines where traits fall within the global distribution. Carbon uptake is more closely associated with specific leaf area for evergreen PFTs and the leaf carbon to nitrogen ratio in deciduous PFTs.

Original language	English
Article number	e2021JG006606
Journal	Journal of Geophysical Research: Biogeosciences
Volume	127
Issue number	3
DOIs	https://doi.org/10.1029/2021JG006606
State	Published - Mar 2022

Funding

This research was supported as part of the Energy Exascale Earth System Model (E3SM) project funded by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research (including Grant DE\u2010SC0012677 to P.B.R.), Biological Integration Institutes Grant NSF\u2010DBI\u20102021898 (to P. B. Reich), and by NSF grants OAC\u20101934634 and IIS\u20101563950 (to A. Banerjee). This research was supported as part of the Energy Exascale Earth System Model (E3SM) project funded by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research (including Grant DE-SC0012677 to P.B.R.), Biological Integration Institutes Grant NSF-DBI-2021898 (to P. B. Reich), and by NSF grants OAC-1934634 and IIS-1563950 (to A. Banerjee).

Keywords

carbon cycle
diversity
functional traits
global models
phenology

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10.1029/2021JG006606

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Butler, E. E., Wythers, K. R., Flores-Moreno, H., Ricciuto, D. M., Datta, A., Banerjee, A., Atkin, O. K., Kattge, J., Thornton, P. E., Anand, M., Burrascano, S., Byun, C., Cornelissen, J. H. C., Forey, E., Jansen, S., Kramer, K., Minden, V., & Reich, P. B. (2022). Increasing Functional Diversity in a Global Land Surface Model Illustrates Uncertainties Related to Parameter Simplification. Journal of Geophysical Research: Biogeosciences, 127(3), Article e2021JG006606. https://doi.org/10.1029/2021JG006606

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abstract = "Simulations of the land surface carbon cycle typically compress functional diversity into a small set of plant functional types (PFT), with parameters defined by the average value of measurements of functional traits. In most earth system models, all wild plant life is represented by between five and 14 PFTs and a typical grid cell (≈100 × 100 km) may contain a single PFT. Model logic applied to this coarse representation of ecological functional diversity provides a reasonable proxy for the carbon cycle, but does not capture the non-linear influence of functional traits on productivity. Here we show through simulations using the Energy Exascale Land Surface Model in 15 diverse terrestrial landscapes, that better accounting for functional diversity markedly alters predicted total carbon uptake. The shift in carbon uptake is as great as 30% and 10% in boreal and tropical regions, respectively, when compared to a single PFT parameterized with the trait means. The traits that best predict gross primary production vary based on vegetation phenology, which broadly determines where traits fall within the global distribution. Carbon uptake is more closely associated with specific leaf area for evergreen PFTs and the leaf carbon to nitrogen ratio in deciduous PFTs.",

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author = "Butler, {Ethan E.} and Wythers, {Kirk R.} and Habacuc Flores-Moreno and Ricciuto, {Daniel M.} and Abhirup Datta and Arindam Banerjee and Atkin, {Owen K.} and Jens Kattge and Thornton, {Peter E.} and Madhur Anand and Sabina Burrascano and Chaeho Byun and Cornelissen, {J. H.C.} and Estelle Forey and Steven Jansen and Koen Kramer and Vanessa Minden and Reich, {Peter B.}",

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year = "2022",

month = mar,

doi = "10.1029/2021JG006606",

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Butler, EE, Wythers, KR, Flores-Moreno, H, Ricciuto, DM, Datta, A, Banerjee, A, Atkin, OK, Kattge, J, Thornton, PE, Anand, M, Burrascano, S, Byun, C, Cornelissen, JHC, Forey, E, Jansen, S, Kramer, K, Minden, V & Reich, PB 2022, 'Increasing Functional Diversity in a Global Land Surface Model Illustrates Uncertainties Related to Parameter Simplification', Journal of Geophysical Research: Biogeosciences, vol. 127, no. 3, e2021JG006606. https://doi.org/10.1029/2021JG006606

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T1 - Increasing Functional Diversity in a Global Land Surface Model Illustrates Uncertainties Related to Parameter Simplification

AU - Butler, Ethan E.

AU - Wythers, Kirk R.

AU - Flores-Moreno, Habacuc

AU - Ricciuto, Daniel M.

AU - Datta, Abhirup

AU - Banerjee, Arindam

AU - Atkin, Owen K.

AU - Kattge, Jens

AU - Thornton, Peter E.

AU - Anand, Madhur

AU - Burrascano, Sabina

AU - Byun, Chaeho

AU - Cornelissen, J. H.C.

AU - Forey, Estelle

AU - Jansen, Steven

AU - Kramer, Koen

AU - Minden, Vanessa

AU - Reich, Peter B.

PY - 2022/3

Y1 - 2022/3

N2 - Simulations of the land surface carbon cycle typically compress functional diversity into a small set of plant functional types (PFT), with parameters defined by the average value of measurements of functional traits. In most earth system models, all wild plant life is represented by between five and 14 PFTs and a typical grid cell (≈100 × 100 km) may contain a single PFT. Model logic applied to this coarse representation of ecological functional diversity provides a reasonable proxy for the carbon cycle, but does not capture the non-linear influence of functional traits on productivity. Here we show through simulations using the Energy Exascale Land Surface Model in 15 diverse terrestrial landscapes, that better accounting for functional diversity markedly alters predicted total carbon uptake. The shift in carbon uptake is as great as 30% and 10% in boreal and tropical regions, respectively, when compared to a single PFT parameterized with the trait means. The traits that best predict gross primary production vary based on vegetation phenology, which broadly determines where traits fall within the global distribution. Carbon uptake is more closely associated with specific leaf area for evergreen PFTs and the leaf carbon to nitrogen ratio in deciduous PFTs.

AB - Simulations of the land surface carbon cycle typically compress functional diversity into a small set of plant functional types (PFT), with parameters defined by the average value of measurements of functional traits. In most earth system models, all wild plant life is represented by between five and 14 PFTs and a typical grid cell (≈100 × 100 km) may contain a single PFT. Model logic applied to this coarse representation of ecological functional diversity provides a reasonable proxy for the carbon cycle, but does not capture the non-linear influence of functional traits on productivity. Here we show through simulations using the Energy Exascale Land Surface Model in 15 diverse terrestrial landscapes, that better accounting for functional diversity markedly alters predicted total carbon uptake. The shift in carbon uptake is as great as 30% and 10% in boreal and tropical regions, respectively, when compared to a single PFT parameterized with the trait means. The traits that best predict gross primary production vary based on vegetation phenology, which broadly determines where traits fall within the global distribution. Carbon uptake is more closely associated with specific leaf area for evergreen PFTs and the leaf carbon to nitrogen ratio in deciduous PFTs.

KW - carbon cycle

KW - diversity

KW - functional traits

KW - global models

KW - phenology

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U2 - 10.1029/2021JG006606

DO - 10.1029/2021JG006606

M3 - Article

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SN - 2169-8953

VL - 127

JO - Journal of Geophysical Research: Biogeosciences

JF - Journal of Geophysical Research: Biogeosciences

IS - 3

M1 - e2021JG006606

ER -

Increasing Functional Diversity in a Global Land Surface Model Illustrates Uncertainties Related to Parameter Simplification

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