How Fragmentation and Corridors Affect Wind Dynamics and Seed Dispersal in Open Habitats

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2014 Feb 26

PMID 24567398

Citations 21

Authors

Ellen I Damschen

Dirk V Baker

Gil Bohrer

Ran Nathan

John L Orrock

Jay R Turner

Lars A Brudvig

Nick M Haddad

Douglas J Levey

Joshua J Tewksbury

Affiliations

Soon will be listed here.

Abstract

Determining how widespread human-induced changes such as habitat loss, landscape fragmentation, and climate instability affect populations, communities, and ecosystems is one of the most pressing environmental challenges. Critical to this challenge is understanding how these changes are affecting the movement abilities and dispersal trajectories of organisms and what role conservation planning can play in promoting movement among remaining fragments of suitable habitat. Whereas evidence is mounting for how conservation strategies such as corridors impact animal movement, virtually nothing is known for species dispersed by wind, which are often mistakenly assumed to not be limited by dispersal. Here, we combine mechanistic dispersal models, wind measurements, and seed releases in a large-scale experimental landscape to show that habitat corridors affect wind dynamics and seed dispersal by redirecting and bellowing airflow and by increasing the likelihood of seed uplift. Wind direction interacts with landscape orientation to determine when corridors provide connectivity. Our results predict positive impacts of connectivity and patch shape on species richness of wind-dispersed plants, which we empirically illustrate using 12 y of data from our experimental landscapes. We conclude that habitat fragmentation and corridors strongly impact the movement of wind-dispersed species, which has community-level consequences.

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