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RESEARCH ARTICLE
Contents Vol 45(2)

Barking up the right tree: comparative use of arboreal and terrestrial artificial refuges to survey reptiles in temperate eucalypt woodlands

Damian R. Michael A B C * , Daniel Florance A * , Mason Crane A , Wade Blanchard A and David B. Lindenmayer A B
+ Author Affiliations
- Author Affiliations

A Fenner School of Environment and Society, The Australian National University, Canberra, ACT 2601, Australia.

B National Environmental Science Program, Threatened Species Recovery Hub, The Australian National University, Canberra, ACT 2601, Australia.

C Corresponding author. Email: damian.michael@anu.edu.au

Wildlife Research 45(2) 185-192 https://doi.org/10.1071/WR17117
Submitted: 22 August 2017  Accepted: 26 February 2018   Published: 24 April 2018

Abstract

Context: Artificial refuges (cover boards) are a popular method to survey and monitor herpetofauna worldwide. However, one limitation of using artificial refuges in terrestrial environments is the low detection rates of arboreal species. Furthermore, destructive search techniques can damage critical microhabitat such as exfoliating rock or flaking bark of mature trees.

Aim: We tested a non-destructive, passive method of sampling arboreal reptiles in fragmented agricultural landscapes in south-eastern Australia.

Methods: We installed 84 artificial bark refuges consisting of strips of non-toxic, closed-cell foam attached to eucalypt trees in 13 patches of remnant vegetation. We used Bayesian statistics to compare differences in detection rates among artificial bark refuges, terrestrial artificial refuges and active searches of natural habitat over a 4-year period.

Key results: Active searches combined with terrestrial artificial refuges detected the highest number of reptile species, including several cryptic fossorial species. Artificial bark refuges detected, on average, 132 times more individuals of the arboreal southern marbled gecko, Christinus marmoratus, than did terrestrial refuges. Gecko abundance patterns were related to tree characteristics such as tree size, bark thickness and stand basal area, as well as survey year.

Conclusions: Traditional survey methods such as terrestrial cover boards, in combination with active searches of natural habitat, may significantly underestimate counts for arboreal gecko species.

Implications: Artificial bark refuges provide a cost-effective, non-destructive and durable method for surveying and monitoring arboreal reptiles in woodland environments over short to medium time frames. Foil-backed, closed-cell foam has broad application for use in spatial capture–recapture studies and long-term monitoring of arboreal reptiles. This method also may be effective for procuring records of threatened arboreal geckos or as a solution for providing temporary habitat in ecological restoration projects.

Additional keywords: arboreal reptiles, artificial cover boards, environmental-impact assessments, habitat restoration, survey method.


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