Frequent and strong cold-air pooling drives temperate forest composition

Melissa A Pastore; Aimée T Classen; Anthony W D'Amato; Marie E English; Karin Rand; Jane R Foster; E Carol Adair

doi:10.1002/ece3.11126

Frequent and strong cold-air pooling drives temperate forest composition

Ecol Evol. 2024 Apr 1;14(4):e11126. doi: 10.1002/ece3.11126. eCollection 2024 Apr.

Authors

Melissa A Pastore^{1

2

3}, Aimée T Classen^{2

4

5}, Anthony W D'Amato¹, Marie E English¹, Karin Rand^{1

4}, Jane R Foster^{1

6}, E Carol Adair^{1

2}

Affiliations

¹ Rubenstein School of Environment and Natural Resources University of Vermont Burlington Vermont USA.
² Gund Institute for Environment, University of Vermont Burlington Vermont USA.
³ USDA Forest Service, Northern Research Station St. Paul Minnesota USA.
⁴ Ecology and Evolutionary Biology Department University of Michigan Ann Arbor Michigan USA.
⁵ University of Michigan Biological Station Pellston Michigan USA.
⁶ USDA Forest Service, Southern Research Station Knoxville Tennessee USA.

Abstract

Cold-air pooling is an important topoclimatic process that creates temperature inversions with the coldest air at the lowest elevations. Incomplete understanding of sub-canopy spatiotemporal cold-air pooling dynamics and associated ecological impacts hinders predictions and conservation actions related to climate change and cold-dependent species and functions. To determine if and how cold-air pooling influences forest composition, we characterized the frequency, strength, and temporal dynamics of cold-air pooling in the sub-canopy at local to regional scales in New England, USA. We established a network of 48 plots along elevational transects and continuously measured sub-canopy air temperatures for 6-10 months (depending on site). We then estimated overstory and understory community temperature preferences by surveying tree composition in each plot and combining these data with known species temperature preferences. We found that cold-air pooling was frequent (19-43% seasonal occurrences) and that sites with the most frequent inversions displayed inverted forest composition patterns across slopes with more cold-adapted species, namely conifers, at low instead of high elevations. We also observed both local and regional variability in cold-air pooling dynamics, revealing that while cold-air pooling is common, it is also spatially complex. Our study, which uniquely focused on broad spatial and temporal scales, has revealed some rarely reported cold-air pooling dynamics. For instance, we discovered frequent and strong temperature inversions that occurred across seasons and in some locations were most frequent during the daytime, likely affecting forest composition. Together, our results show that cold-air pooling is a fundamental ecological process that requires integration into modeling efforts predicting future forest vegetation patterns under climate change, as well as greater consideration for conservation strategies identifying potential climate refugia for cold-adapted species.

Keywords: cold‐air drainage; cold‐air pooling; complex topography; forest composition; microclimate; microrefugia; mountains; temperature inversions.