Projections of changes in the global distribution of shallow water ecosystems through 2100 due to climate change

The global area and distribution of shallow water ecosystems (SWEs), and their projected responses to climate change, are fundamental for evaluating future changes in their ecosystem functions, including biodiversity and climate change mitigation and adaptation. Although previous studies have focuse...

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Bibliographic Details
Published in:PLOS climate 2023-11, Vol.2 (11), p.e0000298
Main Authors: Moki, Hirotada, Yanagita, Keigo, Kondo, Keiichi, Kuwae, Tomohiro
Format: Article
Language:English
Subjects:
Algae
Biodiversity
Carbon
Carbon dioxide
Climate change
Climate change mitigation
Coastal development
Coastal management
Coastal zone management
Ecological function
Ecosystems
Habitats
Land use
Mangroves
Marshes
Ocean temperature
Photosynthetically active radiation
Sea level
Seaweeds
Shallow water
Shrinkage
Temperature
Tidal marshes
Topography
Wave energy
Wave power
Wetlands
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Summary:The global area and distribution of shallow water ecosystems (SWEs), and their projected responses to climate change, are fundamental for evaluating future changes in their ecosystem functions, including biodiversity and climate change mitigation and adaptation. Although previous studies have focused on a few SWEs, we modelled the global distribution of all major SWEs (seagrass meadows, macroalgal beds, tidal marshes, mangroves, and coral habitats) from current conditions (1986–2005) to 2100 under the representative concentration pathway (RCP) 2.6 and 8.5 emission scenarios. Our projections show that global coral habitat shrank by as much as 75% by 2100 with warmer ocean temperatures, but macroalgal beds, tidal marshes, and mangroves remained about the same because photosynthetic active radiation (PAR) depth did not vary greatly (macroalgal beds) and the shrinkage caused by sea-level rise was offset by other areas of expansion (tidal marshes and mangroves). Seagrass meadows were projected to increase by up to 11% by 2100 because of the increased PAR depth. If the landward shift of tidal marshes and mangroves relative to sea-level rise was restricted by assuming coastal development and land use, the SWEs shrank by 91.9% (tidal marshes) and 74.3% (mangroves) by 2100. Countermeasures may be necessary for coastal defense in the future; these include considering the best mix of SWEs and coastal hard infrastructure because the significant shrinkage in coral habitat could not decrease wave energy. However, if appropriate coastal management is achieved, the other four SWEs, which have relatively high CO 2 absorption rates, can help mitigate the climate change influences.
ISSN:2767-3200
2767-3200
DOI:10.1371/journal.pclm.0000298