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Ecological variables for developing a global deep-ocean monitoring and conservation strategy

TitleEcological variables for developing a global deep-ocean monitoring and conservation strategy
Publication TypeJournal Article
Year of Publication2020
AuthorsDanovaro R., Fanelli E., Aguzzi J., Billett D., Carugati L., Corinaldesi C., Dell'Anno A., Gjerde K., Jamieson A.J, Kark S., McClain C., Levin L., Levin N., Ramirez-Llodra E., Ruhl H., Smith C.R, Snelgrove P.VR, Thomsen L., Van Dover C.L, Yasuhara M.
Date Published2020/02
Type of ArticleArticle
ISBN Number2397-334X
Accession NumberWOS:000510791900006
Keywordsbiodiversity; body-size; climate-change; communities; Environmental Sciences & Ecology; Evolutionary Biology; food limitation; impact; productivity; sea; shifts; water

Expert elicitation methods identify a set of essential ecological variables that may be used to guide effective conservation and management of the deep sea. The deep sea (>200 m depth) encompasses >95% of the world's ocean volume and represents the largest and least explored biome on Earth (<0.0001% of ocean surface), yet is increasingly under threat from multiple direct and indirect anthropogenic pressures. Our ability to preserve both benthic and pelagic deep-sea ecosystems depends upon effective ecosystem-based management strategies and monitoring based on widely agreed deep-sea ecological variables. Here, we identify a set of deep-sea essential ecological variables among five scientific areas of the deep ocean: (1) biodiversity; (2) ecosystem functions; (3) impacts and risk assessment; (4) climate change, adaptation and evolution; and (5) ecosystem conservation. Conducting an expert elicitation (1,155 deep-sea scientists consulted and 112 respondents), our analysis indicates a wide consensus amongst deep-sea experts that monitoring should prioritize large organisms (that is, macro- and megafauna) living in deep waters and in benthic habitats, whereas monitoring of ecosystem functioning should focus on trophic structure and biomass production. Habitat degradation and recovery rates are identified as crucial features for monitoring deep-sea ecosystem health, while global climate change will likely shift bathymetric distributions and cause local extinction in deep-sea species. Finally, deep-sea conservation efforts should focus primarily on vulnerable marine ecosystems and habitat-forming species. Deep-sea observation efforts that prioritize these variables will help to support the implementation of effective management strategies on a global scale.

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