Biodiversity Conservation in Urbanising Forested Landscapes
Abstract
Unprecedented human population growth combined with rapid
urbanisation of forest ecosystems highlight an urgent need to
plan for biodiversity conservation in forested landscapes. To
provide scientific evidence to guide management strategies and
urban planning, I studied the distribution and/or abundance of
amphibians and mammals and vegetation structure in a
forest-dominated landscape in south-eastern Australia. In five
scientific papers in three sections, I tackled important gaps of
knowledge on: (1) the distribution of pond-breeding frogs (Paper
I); (2) the distribution and abundance of mammals and vegetation
structure across forest-urban interfaces (Papers II-IV); and (3)
the fate of mammals under future scenarios of compact versus
dispersed urban growth (Paper V).
In the first section, I studied the influence of aquatic and
terrestrial variables on species richness and individual species
occurrence of pond-breeding frogs in an urbanising landscape. I
found the occurrence of common frogs depended on characteristics
of the local aquatic habitat. In contrast, the terrestrial
habitat was important for rare frogs: rare species richness
declined with small increases in road cover as far as 1 km from
the breeding habitat. While provision of aquatic habitat within
urban areas may increase the occurrence of common species, I
identified the need to preserve aquatic habitats within large
forest reserves to conserve urban-sensitive amphibians.
In the second section, I studied the distribution and abundance
of mammals and vegetation structure across forest-urban
interfaces of high and low housing density. For forest-dwelling
mammal species, I found low-density housing developments provided
suitable habitat, whereas high-density housing developments had
low species richness and species abundance. The lower abundance
of forest-dwelling mammals in high-density housing developments
was likely due to a stronger decline of forest vegetation
structures across the forest-urban interface. In addition, I
found the distribution of ground-dwelling mammals was better
explained by local habitat structure (e.g. understorey cover)
than by housing density or distance to an urban boundary. Based
on my findings, I argued for the local-scale management of
vegetation to improve habitat quality for mammals (e.g. to
maintain/provide mature trees and understorey cover). Because a
forest-dwelling species reduced its abundance at long distances
from urban boundaries, I recommended limiting the amount of
forest-urban interfaces when planning for urban development.
In the third section, I quantified the changes in mammal
distribution and abundance at a landscape scale under future
scenarios of compact (i.e. high-density housing) versus dispersed
(i.e. low-density housing) urban growth. Although I previously
found that dispersed development maintained biodiversity, I
discovered that the occurrence and abundance of urban-sensitive
species had a greater decrease under dispersed rather than
compact development. I concluded compact urban growth is less
damaging in landscapes with urban-sensitive fauna than dispersed
development.
Taken together as a connected body of work, my PhD research
demonstrates that positive conservation outcomes will be best
achieved by integrating: local-scale management of habitat to
improve habitat condition for fauna, with land use planning and
urban growth policies. Land planning and urban growth policies
should aim to limit forest clearing and fragmentation, the amount
of forest-urban interfaces, and the sprawl of low-density housing
development.
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