Can Exclusion of Feral Ecosystem Engineers Improve Coastal Floodplain Resilience to Climate Change? Insight from a Case Study in North East Arnhem Land, Australia

Daniel R Sloane; Emilie Ens; Yumutjin Wunungmurra; Lanydjana Mununggurr; Andrew Falk; Richard Wunungmurra; Goninyal Gumana; Gillian Towler; Dave Preece; Yirralka Rangers

doi:10.1007/s00267-024-01940-2

Can Exclusion of Feral Ecosystem Engineers Improve Coastal Floodplain Resilience to Climate Change? Insight from a Case Study in North East Arnhem Land, Australia

Environ Manage. 2024 Feb 15. doi: 10.1007/s00267-024-01940-2. Online ahead of print.

Authors

Daniel R Sloane¹, Emilie Ens², Yumutjin Wunungmurra³, Lanydjana Mununggurr³, Andrew Falk³, Richard Wunungmurra³, Goninyal Gumana³, Gillian Towler³, Dave Preece³; Yirralka Rangers

Affiliations

¹ School of Natural Sciences, Macquarie University, North Ryde, Sydney, NSW, 2109, Australia. daniel.sloane@mq.edu.au.
² School of Natural Sciences, Macquarie University, North Ryde, Sydney, NSW, 2109, Australia.
³ The Yirralka Rangers, Laynhapuy Homelands Aboriginal Corporation, Yirrkala, NT, 0880, Australia.

PMID: 38358512
DOI: 10.1007/s00267-024-01940-2

Abstract

Global climate change can interact with local drivers, such as ecosystem engineers, to exacerbate changes in ecosystem structure and function, with socio-ecological consequences. For regions of Indigenous interest, there may also be cultural consequences if species and areas affected are culturally significant. Here we describe a participatory approach between the Indigenous (Yolngu) Yirralka Rangers and non-Indigenous researchers that explored the interaction between sea level rise and feral ungulate ecosystem engineers on culturally significant floodplains in the Laynhapuy Indigenous Protected Area (IPA), northern Australia. A feral ungulate exclusion fence array (12 fenced and 12 unfenced plots) was stratified by elevation/salinity to disentangle the effects of salinity and ungulates on floodplain soil and vegetation. We found that exclusion of feral ungulates improved ground cover vegetation, which, according to our literature-derived ecosystem process model, may enhance soil trapping and reduce evapotranspiration to provide the antecedent conditions needed to improve floodplain resilience to sea level rise. The mid-zone of the supratidal floodplain study site was suggested as the region where the benefits of fencing were most pronounced after two years and ground cover species diversity was highest. Ongoing monitoring is required to investigate whether removal of feral ungulates can increase resilience against sea level rise and recruitment of eco-culturally significant Melaleuca species. An interview with a key Yolngu Traditional Owner of the study site demonstrated the importance and effectiveness of the partnership. Yolngu land owners and rangers were active co-researchers and will decide if, when and how to integrate results into feral ungulate management and climate adaptation responses, highlighting the importance of industry-university partnerships in maximising biocultural conservation outcomes.

Keywords: Buffalo; Cross-cultural ecology; Cultural ecosystem; Indigenous engagement; Pig; Protected areas.