
Structure is more important than physiology for estimating intracanopy distributions of leaf temperatures
Author(s) -
Woods H. Arthur,
Saudreau Marc,
Pincebourde Sylvain
Publication year - 2018
Publication title -
ecology and evolution
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.17
H-Index - 63
ISSN - 2045-7758
DOI - 10.1002/ece3.4046
Subject(s) - canopy , range (aeronautics) , tree canopy , ecology , vegetation (pathology) , environmental science , atmospheric sciences , biology , medicine , materials science , pathology , composite material , geology
Estimating leaf temperature distributions ( LTD s) in canopies is crucial in forest ecology. Leaf temperature affects the exchange of heat, water, and gases, and it alters the performance of leaf‐dwelling species such as arthropods, including pests and invaders. LTD s provide spatial variation that may allow arthropods to thermoregulate in the face of long‐term changes in mean temperature or incidence of extreme temperatures. Yet, recording LTD s for entire canopies remains challenging. Here, we use an energy‐exchange model ( RATP ) to examine the relative roles of climatic, structural, and physiological factors in influencing three‐dimensional LTD s in tree canopies. A Morris sensitivity analysis of 13 parameters showed, not surprisingly, that climatic factors had the greatest overall effect on LTD s. In addition, however, structural parameters had greater effects on LTD s than did leaf physiological parameters. Our results suggest that it is possible to infer forest canopy LTD s from the LTD s measured or simulated just at the surface of the canopy cover over a reasonable range of parameter values. This conclusion suggests that remote sensing data can be used to estimate 3D patterns of temperature variation from 2D images of vegetation surface temperatures. Synthesis and applications . Estimating the effects of LTD s on natural plant–insect communities will require extending canopy models beyond their current focus on individual species or crops. These models, however, contain many parameters, and applying the models to new species or to mixed natural canopies depends on identifying the parameters that matter most. Our results suggest that canopy structural parameters are more important determinants of LTD s than are the physiological parameters that tend to receive the most empirical attention.