Environmental Research: Climate (Jan 2023)

Thermal acclimation of plant photosynthesis and autotrophic respiration in a northern peatland

  • Shuang Ma,
  • Lifen Jiang,
  • Rachel M Wilson,
  • Jeff Chanton,
  • Shuli Niu,
  • Colleen M Iversen,
  • Avni Malhotra,
  • Jiang Jiang,
  • Yuanyuan Huang,
  • Xingjie Lu,
  • Zheng Shi,
  • Feng Tao,
  • Junyi Liang,
  • Daniel Ricciuto,
  • Paul J Hanson,
  • Yiqi Luo

DOI
https://doi.org/10.1088/2752-5295/acc67e
Journal volume & issue
Vol. 2, no. 2
p. 025003

Abstract

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Peatlands contain one-third of global soil carbon (C), but the responses of peatland ecosystems to long-term warming are not well understood. Here, we pursue an emergent understanding of warming effects on ecosystem C fluxes at peatlands by constraining a process-oriented model, the terrestrial ECOsystem model, with observational data from a long-term warming experiment at the Spruce and Peatland Responses Under Changing Environments site. Model-based assessments show that ecosystem-level photosynthesis and autotrophic respiration exhibited significant thermal acclimation, with temperature sensitivities being linearly decreased with warming. Using the thermal-acclimated parameter values, simulated gross primary production, net primary production, and plant autotrophic respiration ( R _a ), were all lower than those simulated with non-thermal acclimated parameter values. In contrast, ecosystem respiration simulated with thermal acclimated parameter values was higher than that simulated with non-thermal acclimated parameter values. Net ecosystem CO _2 exchange was much higher after constraining model parameters with observational data from the warming treatments, releasing C at a rate of 28.3 g C m ^−2 yr ^−1 °C ^−1 . Our data-model integration study suggests that peatlands are likely to release more C than previously estimated. Earth system models may overestimate C uptake by peatlands under warming if physiological thermal acclimation of plants is not incorporated. Thus, it is critical to consider the long-term physiological thermal acclimation of plants in the models to better predict global C dynamics under future climate and their feedback to climate change.

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