Multi-objective optimization can balance trade-offs among boreal caribou, biodiversity, and climate change objectives when conservation hotspots do not overlap

Multi-objective optimization can balance trade-offs among boreal caribou, biodiversity, and climate change objectives when conservation hotspots do not overlap

The biodiversity and climate change crises have led countries—including Canada—to commit to protect more land and inland waters and to stabilize greenhouse gas concentrations. Canada is also obligated to recover populations of at-risk species, including boreal caribou. Canada has the opportunity to...

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Bibliographic Details
Published in:Scientific reports Vol. 12; no. 1; pp. 11895 - 14
Main Authors: Martin, Amanda E., Neave, Erin, Kirby, Patrick, Drever, C. Ronnie, Johnson, Cheryl A.
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 13-07-2022
Nature Publishing Group
Nature Portfolio
Subjects:
704/158/2449
704/158/672
Animals
Biodiversity
Climate Change
Climate change mitigation
Conservation
Conservation of Natural Resources
Ecosystem
Greenhouse gases
Humanities and Social Sciences
Inland waters
Linear programming
multidisciplinary
Objectives
Protected areas
Refugia
Reindeer
Science
Science (multidisciplinary)
Canada
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Summary:The biodiversity and climate change crises have led countries—including Canada—to commit to protect more land and inland waters and to stabilize greenhouse gas concentrations. Canada is also obligated to recover populations of at-risk species, including boreal caribou. Canada has the opportunity to expand its protected areas network to protect hotspots of high value for biodiversity and climate mitigation. However, co-occurrence of hotspots is rare. Here we ask: is it possible to expand the network to simultaneously protect areas important for boreal caribou, other species at risk, climate refugia, and carbon stores? We used linear programming to prioritize areas for protection based on these conservation objectives, and assessed how prioritization for multiple, competing objectives affected the outcome for each individual objective. Our multi-objective approach produced reasonably strong representation of value across objectives. Although trade-offs were required, the multi-objective outcome was almost always better than when we ignored one objective to maximize value for another, highlighting the risk of assuming that a plan based on one objective will also result in strong outcomes for others. Multi-objective optimization approaches could be used to plan for protected areas networks that address biodiversity and climate change objectives, even when hotspots do not co-occur.
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ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-022-15274-8