DOI: 10.14264/uql.2015.429
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Spatially explicit cost-effective actions for biodiversity threat abatement

Abstract: Biodiversity decline is indisputable, and rates of future decline depend on whether threats to species persistence are abated. However, current resources for threatened species management are less than required to stop further decline. Management that abates many threats to many species is necessary, yet decisions about how to do this under resource constraints are inherently complex. My thesis incorporates systematic conservation planning and cost-effectiveness analysis in a decision-support framework for pri… Show more

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Cited by 3 publications
(3 citation statements)
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References 351 publications
(529 reference statements)
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“…Once a species' target is met, there would be no more value in adding more management area for that species. Systematic conservation planning software (e.g., Moilanen et al 2009;Watts et al 2009) may also be used to account for complementarity; each zone would be a management strategy of combined or single actions (Auerbach 2015). Decision makers can assess whether it is worth collecting more information on different potential actions to address each threat or on the level of interactions between the threats through value-of-information analysis (e.g., Polasky & Solow 2001).…”
Section: Discussionmentioning
confidence: 99%
“…Once a species' target is met, there would be no more value in adding more management area for that species. Systematic conservation planning software (e.g., Moilanen et al 2009;Watts et al 2009) may also be used to account for complementarity; each zone would be a management strategy of combined or single actions (Auerbach 2015). Decision makers can assess whether it is worth collecting more information on different potential actions to address each threat or on the level of interactions between the threats through value-of-information analysis (e.g., Polasky & Solow 2001).…”
Section: Discussionmentioning
confidence: 99%
“…If the approach were to be reapplied in cells of different sizes, the benefits would also need to be weighted by the area over which the benefit is likely to be achieved. Our complementarity-based approach goes beyond a siterichness approach, which typically identifies the locations where actions are most cost-effective (i.e., have high benefits and low costs [Auerbach, 2015]), but ignores complementarity between which species are benefitting from management (Mair et al, 2021). Our approach identifies cells and actions that complement each other (by having different species) and hence have a higher combined benefit than cells selected independently--it considers the idea that the whole is different from the sum of the parts.…”
Section: Maximizing Local Species Richness With a Site-richness Approachmentioning
confidence: 99%
“…According to Keane et al (2001) biophysical models require abundant data, are complex and difficult to understand and require extensive field sampling to construct accurate maps and expertise in fire and fuels modelling. However one advantage is that the method is reproducible and can be updated with new data (Auerbach 2015). In this chapter the FireBGCv2 fire simulation model is assessed as a management tool, however due to the complexity of the model it was not possible to initialise and execute model runs except for simulated landscapes.…”
Section: Introductionmentioning
confidence: 99%