Landscape connectivity: a return to the basics

Philip D. Taylor; Lenore Fahrig; Kimberly A. With

doi:10.1017/CBO9780511754821.003

2 - Landscape connectivity: a return to the basics

Published online by Cambridge University Press: 24 May 2010

Philip D. Taylor ,

Lenore Fahrig and

Kimberly A. With

Edited by

Kevin R. Crooks and

M. Sanjayan

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Kevin R. Crooks: Affiliation:
Colorado State University
M. Sanjayan: Affiliation:
The Nature Conservancy, Virginia

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Summary

INTRODUCTION

In the decade or so since the concept was formalized in landscape ecology (Taylor et al. 1993) the meaning of the term “landscape connectivity” has become rather diffuse and ambiguous. Many researchers continue to ignore key elements of the original concept, which greatly diminishes its potential utility for land management and the conservation of biodiversity. As originally defined, landscape connectivity is “the degree to which the landscape facilitates or impedes movement among resource patches” (Taylor et al. 1993; see also With et al. 1997). This definition emphasizes that the types, amounts, and arrangement of habitat or land use on the landscape influence movement and, ultimately, population dynamics and community structure. Landscape connectivity thus combines a description of the physical structure of the landscape with an organism's response to that structure. In contrast, common usage generally emphasizes only the structural aspect, where landscape connectivity is simply equated with linear features of the landscape that promote dispersal, such as corridors. Moreover, most commonly employed measures of connectivity focus only on how patch area and inter-patch distances affect movement (e.g., Moilanen and Hanski Chapter 3); such measures ignore the rich complexity of how organisms interact with spatial heterogeneity that may ultimately affect dispersal and colonization success (e.g., interactions with patch boundaries, matrix heterogeneity: Wiens et al. 1993; Wiens 1997; Jonsen and Taylor 2000a).

Type: Chapter
Information: Connectivity Conservation , pp. 29 - 43

DOI: https://doi.org/10.1017/CBO9780511754821.003 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2006

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