The hotter it gets, the more forests act as thermal insulators

Environment

Using data from about a hundred sites worldwide, an international research team has demonstrated that forest cover acts as a global thermal insulator, by cooling the understory when the air temperature is high. This buffering effect is a well-known phenomenon, but this study is the first that has evaluated this worldwide in temperate, boreal and tropical forests. Maximum temperatures are on average 4°C lower in forests than outside them, with much higher differences for tropical forests than for the others. The researchers have also shown that the hotter the external conditions, the greater a forest’s buffering capacity.

Based on this observation, management strategies can be proposed to improve forest microclimates and limit the harmful effects of global warming on forest biodiversity. This study published in Nature Ecology & Evolution on 1st April 2019 was an initiative by Pieter De Frenne from Ghent University and Jonathan Lenoir, CNRS researcher at EDYSAN laboratory (CNRS / Université de Picardie Jules Verne).

(Left) Illustration of the microclimate buffer and the separation between the microclimate under a tree canopy and macroclimate outside the forest understory. (Right) Vertical cross section of forest cover (Compiègne state forest) made within a LiDAR point cloud. The upper and lower curves indicate the temperature above and below the forest canopy, respectively: the denser the forest cover and the more confined the topography, the cooler the forest microclimate below the canopy during summer. Plant cover and topography play a role in forests’ ability to insulate.
©Lenoir et al./ONF/CNRS : https://doi.org/10.1111/ecog.02788

 

Bibliography

Global buffering of temperatures under forest canopies. Pieter De Frenne, Florian Zellweger, Francisco Rodríguez-Sánchez, Brett Scheffers, Kristoffer Hylander, Miska Luoto, Mark Vellend, Kris Verheyen and Jonathan Lenoir. Nature Ecology & Evolution, April 1st, 2019. DOI : 10.1038/s41559-019-0842-1

Contact

Jonathan Lenoir
CNRS researcher
François Maginiot
CNRS Press Officer