Increasingly severe thermal stresses on global photosynthesis using insights from observations of canopy temperature

Pan, T., Xu, H., Huntingford, C., Tang, S., Wang, K., Peñuelas, J., & Piao, S. (2026). Increasingly severe thermal stresses on global photosynthesis using insights from observations of canopy temperature. National Science Review 13 (13) nwag347. 10.1093/nsr/nwag347.

[thumbnail of nwag347.pdf]
Preview
Text
nwag347.pdf - Published Version
Available under License Creative Commons Attribution.

Download (2MB) | Preview

Abstract

Temperatures could routinely exceed the optimal levels for photosynthesis as global warming intensifies, imposing thermal stress on the productivity of vegetation. We utilized satellite-derived canopy temperature and gross primary productivity data from 2003 to 2024 to identify the ecosystem-level optimal canopy temperature (${T}^{\rm can}_{\rm opt} $) for global photosynthesis and the extent of any thermal acclimation, which may offset warming impacts. Our findings indicate that across the globe, heat-induced restrictions on global photosynthesis are worsening, and areas subjected to thermal limitations have expanded by 1.7 billion hectares (57% increase) over the last 22 years. The number of days per year with high thermal suppression of photosynthesis during that period has increased sharply, averaging 28 days globally, and is especially high in tropical forests (117 days) and key agricultural regions (39 days). We demonstrate that vegetation acclimation to higher canopy temperature is partially mitigating emerging heat stress, but it is insufficient to keep up with the rate of global warming, with more than 90% of vegetated areas across the globe exhibiting only partial acclimation. A key feature of our analysis is the use of canopy-level temperatures, which more accurately represent the actual temperatures that vegetation physiologically responds to, rather than air temperature used in previous research. This difference accounts for our identified more rapidly intensifying vegetation response to warming than that estimated by other analyses. Overall, our canopy-level analysis reveals an escalating threat to global vegetation productivity and highlights the need for climate models to have refined land components, which often rely on air-temperature forcing and simplified acclimation schemes. Required are targeted ecosystem management strategies for adaptation to further global warming.

Item Type: Article
Uncontrolled Keywords: canopy temperature; gross primary productivity; optimum temperature; thermal acclimation; thermal stress
Research Programs: Biodiversity and Natural Resources (BNR)
Biodiversity and Natural Resources (BNR) > Integrated Biosphere Futures (IBF)
Depositing User: Luke Kirwan
Date Deposited: 13 Jul 2026 08:03
Last Modified: 13 Jul 2026 08:03
URI: https://pure.iiasa.ac.at/21724

Actions (login required)

View Item View Item