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journal article Open Access Apr 01, 2026

Atmospheric Boundary Layer Control on Forest Thermal Properties

Matteo Detto ORCID Christopher Still Amilcare Porporato ORCID
Global Change Biology Vol. 32 No. 4 · Wiley
View at Publisher Save 10.1111/gcb.70841
Abstract
ABSTRACT
Forest canopy, air temperatures and air humidity (, , and ) play a central rol in regulating energy and gas exchange between vegetation and the atmosphere. Although often treated as independent drivers of canopy processes, and are dynamically coupled to via surface energy fluxes and atmospheric boundary layer (ABL) development. We investigated how plant physiology mediates this coupling. Using data from a tropical ecosystem, we studied a process‐based forest model dynamically coupled with an ABL growth model to simulate diurnal interactions between the canopy and the atmosphere. We systematically varied plant traits related to water use and thermal regulation to assess their effects on coupling and feedback. We focused on three metrics: the slope of the relationship, the peak of reached during the day and the lag between the maximum and , indicating hysteresis. Conservative water use, by reducing transpiration, leads to greater canopy warming, which intensifies sensible heat flux and accelerates ABL growth. This, in turn, raises near‐surface air temperature and vapor pressure deficit (VPD), amplifying thermal and water stress. In contrast, greater water use enhances evaporative cooling and slows ABL development, thereby moderating these feedback. Surprisingly, the slope of the relationship is quite insensitive to plant water‐use syndromes. This insight extends beyond modeling. Empirical studies often treat and VPD as independent drivers of transpiration, photosynthesis, or stomatal conductance. Our results challenge this assumption, showing that these variables are influenced by plant function itself. is not a passive outcome but an active mediator of energy, water, and carbon exchange, regulated by a feedback loop involving leaf physiology and atmospheric dynamics. Studies using or the relationship—whether from remote sensing or field data—as a proxy for forest stress or function, must account for this coupling.
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Details
Published
Apr 01, 2026
Vol/Issue
32(4)
License
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Authors
M
Matteo Detto

High Meadows Environmental Institute Princeton University Princeton New Jersey USA; Smithsonian Tropical Research Institute Balboa Republic of Panama

C
Christopher Still

Department of Forest Ecosystems and Society Oregon State University Corvallis Oregon USA

A
Amilcare Porporato

High Meadows Environmental Institute Princeton University Princeton New Jersey USA; Department of Civil and Environmental Engineering Princeton University Princeton New Jersey USA

Funding
Office of Science
U.S. Department of Energy
Cite This Article
Matteo Detto, Christopher Still, Amilcare Porporato (2026). Atmospheric Boundary Layer Control on Forest Thermal Properties. Global Change Biology, 32(4). https://doi.org/10.1111/gcb.70841
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