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Stress protection of Amazon trees, induced by climate warming, may alter atmosphere chemistry

The Amazon rainforest is one of the largest carbon reservoirs on Earth. It is also the world's largest source of biogenic volatile organic compounds (VOCs). These carbon-based gases are naturally released ...

Amazon rainforest
Credit: Quang Nguyen Vinh from Pexels

The Amazon rainforest is one of the largest carbon reservoirs on Earth. It is also the world's largest source of biogenic volatile organic compounds (VOCs). These carbon-based gases are naturally released by vegetation. They protect trees against various sources of stress, e.g., by mitigating oxidative stress and deterring herbivores. Once in the atmosphere, VOCs react rapidly with other gases. This influences the formation of airborne particles and clouds, which contributes to shaping the regional climate and rainfall patterns.

Researchers from the Max Planck Institute for Biogeochemistry and the National Institute of Amazonian Research (INPA) analyzed how a warming world might change emissions of VOCs. At the Amazon Tall Tower Observatory (ATTO) site in the remote Amazon rainforest, the scientists measured the trees' emissions of different VOCs, as well as their key physiological traits linked to photosynthesis and heat tolerance. Their findings are published in Communications Earth & Environment.

They focused on two major ecological groups that differ in their leaf-turnover strategy to compare their heat-induced VOC emission response. Evergreen trees are the most prevalent in the Amazon and retain their leaves year-round. In contrast, brevideciduous trees massively replace their canopies and remain leafless for up to one month during each year's dry season.

The researchers found that higher leaf temperatures triggered substantially higher emissions of VOCs. Additionally, they revealed a shift from the emission of isoprene (five carbon atoms) to the highly reactive, carbon-rich monoterpenes (10 carbon atoms) and sesquiterpenes (15 carbon atoms). This shift was particularly evident in brevideciduous trees.

Monoterpenes and sesquiterpenes are among the most chemically reactive gases released by vegetation and can strongly affect atmospheric processes. The shift toward higher emissions, and the emission of compounds with more carbon atoms, also means that forests lose more carbon to the atmosphere as temperatures rise.

"We also noticed that different tree groups use different physiological strategies in the face of heat stress," says Michelle Robin, lead author and postdoctoral researcher at the Max Planck Institute for Biogeochemistry. Isoprene-emitting brevideciduous tree species have higher baseline photosynthetic rates.

This suggests that they rely on the mitigating effects of the biogenic volatiles as a strategy to respond to heat stress. However, evergreen tree species that did not emit isoprene exhibited greater baseline stomatal conductance, allowing cooling by transpiration of water vapor, and stronger thermal stability across several photochemical traits. This indicates that these trees use a different strategy to cope with heat, one centered on sustained physiological stability.

Prior studies have shown that dry-season leaf turnover may serve as a protection mechanism against drought and herbivory stress. Importantly, trees can transition from evergreen to brevideciduous in response to stress and disturbances. As a consequence, with continued climate warming and frequent heat waves, the Amazon rainforest could see a shift toward brevideciduous leaf-turnover strategies, which could further amplify emissions of biogenic volatile organic compounds.

Finally, the team tested whether accounting for leaf-turnover strategies could improve the accuracy of isoprene emission estimates in a global vegetation emission model. The commonly used default approaches substantially overestimated isoprene fluxes. "Our results show that models incorporating phenologically informed parameters derived from field measurements at the ATTO site produced more realistic emission estimates," concluded Eliane Gomes Alves, project group leader at the Max Planck Institute for Biogeochemistry.

Climate projections indicate that the Amazon region will experience rising temperatures and more frequent heat extremes in the coming decades. The new findings suggest that this could alter how trees allocate carbon, i.e., the amount and type of compounds they release into the atmosphere. Since these emissions influence atmospheric reactivity, aerosol formation, cloud development and carbon cycling, even minor changes in emission patterns could affect climate processes on regional and potentially global scales.

Publication details

Michelle Robin et al, Coordinated volatile isoprenoid production and leaf turnover strategy protect central Amazon Forest trees against stress, Communications Earth & Environment (2026). DOI: 10.1038/s43247-026-03668-9

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Lisa Lock

Lisa Lock

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Andrew Zinin

Andrew Zinin

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Citation: Stress protection of Amazon trees, induced by climate warming, may alter atmosphere chemistry (2026, July 9) retrieved 12 July 2026 from https://phys.org/news/2026-07-stress-amazon-trees-climate-atmosphere.html

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