Towards climate-smart, three-dimensional protected areas for biodiversity conservation in the high seas

被引:0
作者
Isaac Brito-Morales
David S. Schoeman
Jason D. Everett
Carissa J. Klein
Daniel C. Dunn
Jorge García Molinos
Michael T. Burrows
Kristine Camille V. Buenafe
Rosa Mar Dominguez
Hugh P. Possingham
Anthony J. Richardson
机构
[1] The University of Queensland,School of Earth and Environmental Sciences
[2] Commonwealth Scientific and Industrial Research Organisation (CSIRO) Oceans and Atmosphere,Queensland Biosciences Precinct (QBP)
[3] The University of Queensland,School of Mathematics and Physics
[4] Conservation International,Betty and Gordon Moore Center for Science
[5] University of the Sunshine Coast,Global
[6] Nelson Mandela University,Change Ecology Research Group, School of Science, Technology and Engineering
[7] The University of New South Wales,Centre for African Conservation Ecology, Department of Zoology
[8] The University of Queensland,Centre for Marine Science and Innovation (CMSI)
[9] Hokkaido University,Centre for Biodiversity and Conservation Science (CBCS)
[10] Hokkaido University,Arctic Research Center
[11] Hokkaido University,Global Station for Arctic Research, Global Institution for Collaborative Research and Education
[12] Scottish Association for Marine Science,Graduate School of Environmental Science
来源
Nature Climate Change | 2022年 / 12卷
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摘要
Marine species are moving rapidly in response to warming, often in different directions and with variations dependent on location and depth. Given the current impetus to increase the area of protected ocean to 30%, conservation planning must include the 64% of the ocean beyond national jurisdictions, which in turn requires associated design challenges for conventional conservation to be addressed. Here we present a planning approach for the high seas that conserves biodiversity, minimizes exposure to climate change, retains species within reserve boundaries and reduces conflict with fishing. This is developed using data from across four depth domains, considering 12,932 vertebrate, invertebrate and algal species and three climate scenarios. The resultant climate-smart conservation areas cover 6% of the high seas and represent a low-regret option that provides a nucleus for developing a full network of high-seas marine reserves.
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页码:402 / 407
页数:5
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