ID:
publications-1721
Type:
Peer reviewed articles
Year:
2021
Authors:
Aliénor Lavergne, Deborah Hemming, Iain Colin Prentice, Rossella Guerrieri, Rebecca J. Oliver, Heather Graven
Title:
Global decadal variability of plant carbon isotope discrimination and its link to gross primary production
Venue/Journal:
Global Change Biology
DOI:
10.1111/gcb.15924
Research type:
Uncategorized
Water System:
Uncategorized
Technical Focus:
Abstract:
AbstractCarbon isotope discrimination (Î13C) in C3 woody plants is a key variable for the study of photosynthesis. Yet how Î13C varies at decadal scales, and across regions, and how it is related to gross primary production (GPP), are still incompletely understood. Here we address these questions by implementing a new Î13C modelling capability in the landâsurface model JULES incorporating both photorespiratory and mesophyllâconductance fractionations. We test the ability of four leafâinternal CO2 concentration models embedded in JULES to reproduce leaf and treeâring (TR) carbon isotopic data. We show that all the tested models tend to overestimate average Î13C values, and to underestimate interannual variability in Î13C. This is likely because they ignore the effects of soil water stress on stomatal behavior. Variations in postâphotosynthetic isotopic fractionations across species, sites and years, may also partly explain the discrepancies between predicted and TRâderived Î13C values. Nonetheless, the âleastâcostâ (Prentice) model shows the lowest biases with the isotopic measurements, and lead to improved predictions of canopyâlevel carbon and water fluxes. Overall, modelled Î13C trends vary strongly between regions during the recent (1979â2016) historical period but stay nearly constant when averaged over the globe. Photorespiratory and mesophyll effects modulate the simulated global Î13C trend by 0.0015 ± 0.005â° and â0.0006 ± 0.001â° ppmâ1, respectively. These predictions contrast with previous findings based on atmospheric carbon isotope measurements. Predicted Î13C and GPP tend to be negatively correlated in wetâhumid and cold regions, and in tropical African forests, but positively related elsewhere. The negative correlation between Î13C and GPP is partly due to the strong dominant influences of temperature on GPP and vapor pressure deficit on Î13C in those forests. Our results demonstrate that the combined analysis of Î13C and GPP can help understand the drivers of photosynthesis changes in different climatic regions.
Link with Projects:
787203
Link with Tools:
Related policies:
ID:
