Habitat corridors maintain biodiversity and healthy ecosystems in fragmented landscapes
Connected habitats essential to ecological
integrity
Preserving habitat corridors, thin strips of remnant habitat
linking disconnected areas of natural habitat, to create habitat
networks is a promising conservation strategy that can sustain
biodiversity and ecosystem processes, according to a new 平特五不中
University-led study.
Biological diversity plays a critical role in the way ecosystems
function by contributing to nutrient recycling, carbon storage,
climate regulation, and resistance to invasive species. Globally,
man-made habitat loss and fragmentation is causing biodiversity
loss, which in turn is breaking the link between biodiversity and
ecosystem functions.
In a study by Andrew Gonzalez, Professor and Canada Research Chair
in Biodiversity, and team in the Department of Biology at 平特五不中,
and collaborators at the University of Nottingham in the UK to be
published in the up-and-coming journal Ecology Letters, discovered
the crucial role connected habitats play in maintaining
biodiversity.
The team shrunk the difficult problem of studying ecosystems to
manageable proportions by using a model ecosystem in a controlled
laboratory experiment. They created small-scale fragmented
landscapes, and over the course of a year monitored how the
diversity of microscopic organisms, and several important ecosystem
processes, changed in response to this experimental
manipulation.
They discovered that habitat connected by corridors lost fewer
species than isolated fragments, and, crucially, maintained
ecosystem processes in a manner more similar to large, intact,
habitats. Corridors work by allowing organisms to move between
habitat fragments.
Corridors thus restore the vital link between biodiversity and
ecosystem functions. The research by Gonzalez鈥檚 team shows that
connected habitat is essential for the preservation of the complex
web of species interactions and processes so important for
ecosystem services and human well-being.
The research was funded by the Natural Environment Research Council
(NERC), UK; Natural Science and Engineering Research Council of
Canada (NSERC); and the Canada Research Chair Program (CRC).