Forest Annual Carbon Cost: a Global-scale Analysis of Autotrophic Respiration

Overview

Journal Ecology

Specialty Environmental Health

Date 2010 Apr 30

PMID 20426325

Citations 19

Authors

Shilong Piao

Sebastiaan Luyssaert

Philippe Ciais

Ivan A Janssens

Anping Chen

Chao Cao

Jingyun Fang

Pierre Friedlingstein

Yiqi Luo

Shaopeng Wang

Affiliations

Soon will be listed here.

Abstract

Forest autotrophic respiration (R(a)) plays an important role in the carbon balance of forest ecosystems. However, its drivers at the global scale are not well known. Based on a global forest database, we explore the relationships of annual R(a) with mean annual temperature (MAT) and biotic factors including net primary productivity (NPP), total biomass, stand age, mean tree height, and maximum leaf area index (LAI). The results show that the spatial patterns of forest annual R(a) at the global scale are largely controlled by temperature. R(a) is composed of growth (R(g)) and maintenance respiration (R(m)). We used a modified Arrhenius equation to express the relationship between R(a) and MAT. This relationship was calibrated with our data and shows that a 10 degrees C increase in MAT will result in an increase of annual R(m) by a factor of 1.9-2.5 (Q10). We also found that the fraction of total assimilation (gross primary production, GPP) used in R(a) is lowest in the temperate regions characterized by a MAT of approximately 11 degrees C. Although we could not confirm a relationship between the ratio of R(a) to GPP and age across all forest sites, the R(a) to GPP ratio tends to significantly increase in response to increasing age for sites with MAT between 8 degrees and 12 degrees C. At the plant scale, direct up-scaled R(a) estimates were found to increase as a power function with forest total biomass; however, the coefficient of the power function (0.2) was much smaller than that expected from previous studies (0.75 or 1). At the ecosystem scale, R(a) estimates based on both GPP - NPP and TER - R(h) (total ecosystem respiration - heterotrophic respiration) were not significantly correlated with forest total biomass (P > 0.05) with either a linear or a power function, implying that the previous individual-based metabolic theory may be not suitable for the application at ecosystem scale.

Citing Articles

Biome-scale temperature sensitivity of ecosystem respiration revealed by atmospheric CO observations.

Sun W, Luo X, Fang Y, Shiga Y, Zhang Y, Fisher J Nat Ecol Evol. 2023; 7(8):1199-1210.

PMID: 37322104 PMC: 10406605. DOI: 10.1038/s41559-023-02093-x.

It's only natural: Plant respiration in unmanaged systems.

Schmiege S, Heskel M, Fan Y, Way D Plant Physiol. 2023; 192(2):710-727.

PMID: 36943293 PMC: 10231469. DOI: 10.1093/plphys/kiad167.

Historically inconsistent productivity and respiration fluxes in the global terrestrial carbon cycle.

Jian J, Bailey V, Dorheim K, Konings A, Hao D, Shiklomanov A Nat Commun. 2022; 13(1):1733.

PMID: 35365658 PMC: 8976082. DOI: 10.1038/s41467-022-29391-5.

Impact of rising temperatures on the biomass of humid old-growth forests of the world.

Larjavaara M, Lu X, Chen X, Vastaranta M Carbon Balance Manag. 2021; 16(1):31.

PMID: 34642849 PMC: 8513374. DOI: 10.1186/s13021-021-00194-3.

Reference carbon cycle dataset for typical Chinese forests via colocated observations and data assimilation.

He H, Ge R, Ren X, Zhang L, Chang Q, Xu Q Sci Data. 2021; 8(1):42.

PMID: 33531507 PMC: 7854661. DOI: 10.1038/s41597-021-00826-w.