Abstract
As a result of the increasing speed and magnitude in which habitats worldwide are experiencing environmental change, making accurate predictions of the effects of global change on ecosystems and the organisms that inhabit them have become an important goal for ecologists. Experimental and modelling approaches aimed at understanding the linkages between factors of global change and biotic responses have become numerous and increasingly complex in order to adequately capture the multifarious dynamics associated with these relationships. However, constrained by resources, experiments are often conducted at small spatiotemporal scales (e.g. looking at a plot of a few square metres over a few years) and at low organizational levels (looking at organisms rather than ecosystems) in spite of both theoretical and experimental work that suggests ecological dynamics across scales can be dissimilar. This phenomenon has been hypothesized to occur because the mechanisms that drive dynamics across scales differ. A good example is the effect of elevated CO2 on transpiration. While at the leaf level, transpiration can be reduced, at the stand level, transpiration can increase because leaf area per unit ground area increases. The reported net effect is then highly dependent on the spatiotemporal scale. This special issue considers the biological relevancy inherent in the patterns associated with the magnitude and type of response to changing environmental conditions, across scales. This collection of papers attempts to provide a comprehensive treatment of this phenomenon in order to help develop an understanding of the extent of, and mechanisms involved with, ecological response to global change.
Highlights
Introduction to the Special IssueAcross the horizon: scale effects in global change researchElise S
Gornish and Leuzinger — Scale effects in global change research response to a changing environment. This is problematic because the design and implementation of broad-scale management strategies to address conservation issues in the face of global change is often informed through extrapolating the more voluminous and detailed results of research conducted at local or small spatial scales to large scales (e.g. Hairston 1990; Cheruvelil et al 2013), even though local-scale dynamics might not linearly translate to larger-scale patterns (Jarvis and McNaughton 1986; Donalson and Nisbet 1999; Tricker et al 2009; Harte 2011; Supp et al 2012)
At small scales, drought appears to be the major driver of treehole mosquito diversity and abundance, but at larger scales, drought does not explain variation in mosquito number (Srivastava 2005). This is thought to occur because the mechanisms that drive dynamics across scales differ (e.g. Supp and Ernest 2014)
Summary
Introduction to the Special Issue: Across the horizon: scale effects in global change research.
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