Data from: Harvesting wildlife affected by climate change: a modelling and management approach for polar bears

The conservation of many wildlife species requires understanding the demographic effects of climate change, including interactions between climate change and harvest, which can provide cultural, nutritional or economic value to humans. We present a demographic model that is based on the polar bear U...

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Bibliographic Details
Main Authors: Regehr, Eric V., Wilson, Ryan R., Rode, Karyn D., Runge, Michael C., Stern, Harry L.
Format: Article in Journal/Newspaper
Language:unknown
Published: 2017
Subjects:
conservation
density dependence
habitat loss
hunting
state-dependent management
sustainable
threatened
risk
harvest
polar bear
Arctic
Climate change
Sea ice
Ursus maritimus
Alaska
Online Access:http://hdl.handle.net/10255/dryad.134106
https://doi.org/10.5061/dryad.f68m0
id ftdryad:oai:v1.datadryad.org:10255/dryad.134106
record_format openpolar
spelling ftdryad:oai:v1.datadryad.org:10255/dryad.134106 2023-05-15T15:18:46+02:00 Data from: Harvesting wildlife affected by climate change: a modelling and management approach for polar bears Regehr, Eric V. Wilson, Ryan R. Rode, Karyn D. Runge, Michael C. Stern, Harry L. Arctic Alaska 2017-03-08T12:56:04Z http://hdl.handle.net/10255/dryad.134106 https://doi.org/10.5061/dryad.f68m0 unknown doi:10.5061/dryad.f68m0/1 doi:10.5061/dryad.f68m0/2 doi:10.1111/1365-2664.12864 doi:10.5061/dryad.f68m0 Regehr EV, Wilson RR, Rode KD, Runge MC, Stern HL (2017) Harvesting wildlife affected by climate change: a modelling and management approach for polar bears. Journal of Applied Ecology 54(5): 1534-1543. 0021-8901 http://hdl.handle.net/10255/dryad.134106 conservation density dependence habitat loss hunting state-dependent management sustainable threatened risk harvest polar bear Article 2017 ftdryad https://doi.org/10.5061/dryad.f68m0 https://doi.org/10.5061/dryad.f68m0/1 https://doi.org/10.5061/dryad.f68m0/2 https://doi.org/10.1111/1365-2664.12864 2020-01-01T15:44:36Z The conservation of many wildlife species requires understanding the demographic effects of climate change, including interactions between climate change and harvest, which can provide cultural, nutritional or economic value to humans. We present a demographic model that is based on the polar bear Ursus maritimus life cycle and includes density-dependent relationships linking vital rates to environmental carrying capacity (K). Using this model, we develop a state-dependent management framework to calculate a harvest level that (i) maintains a population above its maximum net productivity level (MNPL; the population size that produces the greatest net increment in abundance) relative to a changing K, and (ii) has a limited negative effect on population persistence. Our density-dependent relationships suggest that MNPL for polar bears occurs at approximately 0·69 (95% CI = 0·63–0·74) of K. Population growth rate at MNPL was approximately 0·82 (95% CI = 0·79–0·84) of the maximum intrinsic growth rate, suggesting relatively strong compensation for human-caused mortality. Our findings indicate that it is possible to minimize the demographic risks of harvest under climate change, including the risk that harvest will accelerate population declines driven by loss of the polar bear's sea-ice habitat. This requires that (i) the harvest rate – which could be 0 in some situations – accounts for a population's intrinsic growth rate, (ii) the harvest rate accounts for the quality of population data (e.g. lower harvest when uncertainty is large), and (iii) the harvest level is obtained by multiplying the harvest rate by an updated estimate of population size. Environmental variability, the sex and age of removed animals and risk tolerance can also affect the harvest rate. Synthesis and applications. We present a coupled modelling and management approach for wildlife that accounts for climate change and can be used to balance trade-offs among multiple conservation goals. In our example application to polar bears experiencing sea-ice loss, the goals are to maintain population viability while providing continued opportunities for subsistence harvest. Our approach may be relevant to other species for which near-term management is focused on human factors that directly influence population dynamics within the broader context of climate-induced habitat degradation. Article in Journal/Newspaper Arctic Climate change polar bear Sea ice Ursus maritimus Alaska Dryad Digital Repository (Duke University) Arctic
institution Open Polar
collection Dryad Digital Repository (Duke University)
op_collection_id ftdryad
language unknown
topic conservation
density dependence
habitat loss
hunting
state-dependent management
sustainable
threatened
risk
harvest
polar bear
spellingShingle conservation
density dependence
habitat loss
hunting
state-dependent management
sustainable
threatened
risk
harvest
polar bear
Regehr, Eric V.
Wilson, Ryan R.
Rode, Karyn D.
Runge, Michael C.
Stern, Harry L.
Data from: Harvesting wildlife affected by climate change: a modelling and management approach for polar bears
topic_facet conservation
density dependence
habitat loss
hunting
state-dependent management
sustainable
threatened
risk
harvest
polar bear
description The conservation of many wildlife species requires understanding the demographic effects of climate change, including interactions between climate change and harvest, which can provide cultural, nutritional or economic value to humans. We present a demographic model that is based on the polar bear Ursus maritimus life cycle and includes density-dependent relationships linking vital rates to environmental carrying capacity (K). Using this model, we develop a state-dependent management framework to calculate a harvest level that (i) maintains a population above its maximum net productivity level (MNPL; the population size that produces the greatest net increment in abundance) relative to a changing K, and (ii) has a limited negative effect on population persistence. Our density-dependent relationships suggest that MNPL for polar bears occurs at approximately 0·69 (95% CI = 0·63–0·74) of K. Population growth rate at MNPL was approximately 0·82 (95% CI = 0·79–0·84) of the maximum intrinsic growth rate, suggesting relatively strong compensation for human-caused mortality. Our findings indicate that it is possible to minimize the demographic risks of harvest under climate change, including the risk that harvest will accelerate population declines driven by loss of the polar bear's sea-ice habitat. This requires that (i) the harvest rate – which could be 0 in some situations – accounts for a population's intrinsic growth rate, (ii) the harvest rate accounts for the quality of population data (e.g. lower harvest when uncertainty is large), and (iii) the harvest level is obtained by multiplying the harvest rate by an updated estimate of population size. Environmental variability, the sex and age of removed animals and risk tolerance can also affect the harvest rate. Synthesis and applications. We present a coupled modelling and management approach for wildlife that accounts for climate change and can be used to balance trade-offs among multiple conservation goals. In our example application to polar bears experiencing sea-ice loss, the goals are to maintain population viability while providing continued opportunities for subsistence harvest. Our approach may be relevant to other species for which near-term management is focused on human factors that directly influence population dynamics within the broader context of climate-induced habitat degradation.
format Article in Journal/Newspaper
author Regehr, Eric V.
Wilson, Ryan R.
Rode, Karyn D.
Runge, Michael C.
Stern, Harry L.
author_facet Regehr, Eric V.
Wilson, Ryan R.
Rode, Karyn D.
Runge, Michael C.
Stern, Harry L.
author_sort Regehr, Eric V.
title Data from: Harvesting wildlife affected by climate change: a modelling and management approach for polar bears
title_short Data from: Harvesting wildlife affected by climate change: a modelling and management approach for polar bears
title_full Data from: Harvesting wildlife affected by climate change: a modelling and management approach for polar bears
title_fullStr Data from: Harvesting wildlife affected by climate change: a modelling and management approach for polar bears
title_full_unstemmed Data from: Harvesting wildlife affected by climate change: a modelling and management approach for polar bears
title_sort data from: harvesting wildlife affected by climate change: a modelling and management approach for polar bears
publishDate 2017
url http://hdl.handle.net/10255/dryad.134106
https://doi.org/10.5061/dryad.f68m0
op_coverage Arctic
Alaska
geographic Arctic
geographic_facet Arctic
genre Arctic
Climate change
polar bear
Sea ice
Ursus maritimus
Alaska
genre_facet Arctic
Climate change
polar bear
Sea ice
Ursus maritimus
Alaska
op_relation doi:10.5061/dryad.f68m0/1
doi:10.5061/dryad.f68m0/2
doi:10.1111/1365-2664.12864
doi:10.5061/dryad.f68m0
Regehr EV, Wilson RR, Rode KD, Runge MC, Stern HL (2017) Harvesting wildlife affected by climate change: a modelling and management approach for polar bears. Journal of Applied Ecology 54(5): 1534-1543.
0021-8901
http://hdl.handle.net/10255/dryad.134106
op_doi https://doi.org/10.5061/dryad.f68m0
https://doi.org/10.5061/dryad.f68m0/1
https://doi.org/10.5061/dryad.f68m0/2
https://doi.org/10.1111/1365-2664.12864
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