Ecology and Evolution (Oct 2022)

Integrating natural gradients, experiments, and statistical modeling in a distributed network experiment: An example from the WaRM Network

  • Case M. Prager,
  • Aimee T. Classen,
  • Maja K. Sundqvist,
  • Maria Noelia Barrios‐Garcia,
  • Erin K. Cameron,
  • Litong Chen,
  • Chelsea Chisholm,
  • Thomas W. Crowther,
  • Julie R. Deslippe,
  • Karl Grigulis,
  • Jin‐Sheng He,
  • Jeremiah A. Henning,
  • Mark Hovenden,
  • Toke T. Thomas Høye,
  • Xin Jing,
  • Sandra Lavorel,
  • Jennie R. McLaren,
  • Daniel B. Metcalfe,
  • Gregory S. Newman,
  • Marie Louise Nielsen,
  • Christian Rixen,
  • Quentin D. Read,
  • Kenna E. Rewcastle,
  • Mariano Rodriguez‐Cabal,
  • David A. Wardle,
  • Sonja Wipf,
  • Nathan J. Sanders

DOI
https://doi.org/10.1002/ece3.9396
Journal volume & issue
Vol. 12, no. 10
pp. n/a – n/a

Abstract

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Abstract A growing body of work examines the direct and indirect effects of climate change on ecosystems, typically by using manipulative experiments at a single site or performing meta‐analyses across many independent experiments. However, results from single‐site studies tend to have limited generality. Although meta‐analytic approaches can help overcome this by exploring trends across sites, the inherent limitations in combining disparate datasets from independent approaches remain a major challenge. In this paper, we present a globally distributed experimental network that can be used to disentangle the direct and indirect effects of climate change. We discuss how natural gradients, experimental approaches, and statistical techniques can be combined to best inform predictions about responses to climate change, and we present a globally distributed experiment that utilizes natural environmental gradients to better understand long‐term community and ecosystem responses to environmental change. The warming and (species) removal in mountains (WaRM) network employs experimental warming and plant species removals at high‐ and low‐elevation sites in a factorial design to examine the combined and relative effects of climatic warming and the loss of dominant species on community structure and ecosystem function, both above‐ and belowground. The experimental design of the network allows for increasingly common statistical approaches to further elucidate the direct and indirect effects of warming. We argue that combining ecological observations and experiments along gradients is a powerful approach to make stronger predictions of how ecosystems will function in a warming world as species are lost, or gained, in local communities.

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