Correctly applying lapse rates in ecological studies: comparing temperature observations and gridded data in Yellowstone

Michael T. Tercek; Ann Rodman; Shannon Woolfolk; Zachary Wilson; David Thoma; John Gross

doi:10.1002/ecs2.3451

Ecosphere (Mar 2021)

Correctly applying lapse rates in ecological studies: comparing temperature observations and gridded data in Yellowstone

Michael T. Tercek,
Ann Rodman,
Shannon Woolfolk,
Zachary Wilson,
David Thoma,
John Gross

Affiliations

Michael T. Tercek: Walking Shadow Ecology PO Box 1085 Gardiner Montana59030USA
Ann Rodman: Yellowstone Center for Resources US National Park Service PO Box 168 Yellowstone National Park Wyoming82190USA
Shannon Woolfolk: Yellowstone Center for Resources US National Park Service PO Box 168 Yellowstone National Park Wyoming82190USA
Zachary Wilson: Yellowstone Center for Resources US National Park Service PO Box 168 Yellowstone National Park Wyoming82190USA
David Thoma: US National Park Service, Inventory and Monitoring Program 2327 University Way Suite 2 Bozeman Montana59715USA
John Gross: US National Park Service Climate Change Response Program 1201 Oakridge Drive Suite 200 Fort Collins Colorado80525USA

DOI: https://doi.org/10.1002/ecs2.3451
Journal volume & issue: Vol. 12, no. 3
pp. n/a – n/a

Abstract

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Abstract Researchers often use gridded datasets to develop statistical relationships between climate and natural resources at locations that are distant from weather stations. These gridded datasets may provide inaccurate estimates of temperature at sites with elevations that differ significantly from the elevation assigned to the corresponding grid cell. We assess the accuracy of three gridded climate datasets commonly used in ecological studies (800‐m resolution PRISM, 4‐km GRIDMET, and 1‐km Daymet) compared with a network of 153 temperature dataloggers arranged along elevation transects in Yellowstone National Park (Wyoming, Montana, Idaho). Measured lapse rates for monthly average daytime high temperatures were generally steeper (more cooling per unit of elevation increase) than lapse rates in gridded datasets and steeper than those in similar mountainous regions. Measured lapse rates for monthly average nighttime lows were similar to gridded data lapse rates. Our measured lapse rates are most useful for the adjustment of daytime highs from weather stations or gridded data during warmer months. Temperatures during cooler months sometimes are strongly affected by other factors. Ecologically relevant metrics calculated from temperatures adjusted with constant lapse rates can increase multiplicatively and by varying amounts from year to year. For example, high‐elevation estimates of climatic water deficit (CWD) calculated from gridded data that were not adjusted with our measured lapse rates were 2.5–4 times greater (depending on the year) than calculations from temperatures that were adjusted. Our results emphasize the importance of correcting grid‐based climate estimates for elevation in complex terrain when accurate, site‐specific data are required. When the elevation assigned to grid cells differs significantly from the elevation of points within the cell, the lapse rate obtained for data extracted from grids can be shallower than the true rate. We illustrate the implications of these findings with case studies in Yellowstone.

Published in Ecosphere

ISSN: 2150-8925 (Online)
Publisher: Wiley
Country of publisher: United States
LCC subjects: Science: Biology (General): Ecology
Website: http://esajournals.onlinelibrary.wiley.com/hub/journal/10.1002/(ISSN)2150-8925/

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