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CO2 leakage can cause loss of benthic biodiversity in submarine sands
Molari, M.; Guilini, K.; Lins, L.; Ramette, A.; Vanreusel, A. (2019). CO2 leakage can cause loss of benthic biodiversity in submarine sands. Mar. Environ. Res. 144: 213-229. https://dx.doi.org/10.1016/j.marenvres.2019.01.006
In: Marine Environmental Research. Applied Science Publishers: Barking. ISSN 0141-1136; e-ISSN 1879-0291
Peer reviewed article  

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Keywords
    Aquatic communities > Benthos
    Biodiversity
    Microorganisms > Bacteria
    Marine/Coastal
Author keywords
    Invertebrates; CO2 vents; Carbon capture and storage (CCS); Panarea island; Mediterranean sea

Authors  Top 
  • Molari, M.
  • Guilini, K., more
  • Lins, L., more
  • Ramette, A.
  • Vanreusel, A., more

Abstract
    One of the options to mitigate atmospheric CO2 increase is CO2 Capture and Storage in sub-seabed geological formations. Since predicting long-term storage security is difficult, different CO2 leakage scenarios and impacts on marine ecosystems require evaluation. Submarine CO2 vents may serve as natural analogues and allow studying the effects of CO2 leakage in a holistic approach. At the study site east of Basiluzzo Islet off Panarea Island (Italy), gas emissions (90–99% CO2) occur at moderate flows (80–120 L m−2 h−1). We investigated the effects of acidified porewater conditions (pHT range: 5.5–7.7) on the diversity of benthic bacteria and invertebrates by sampling natural sediments in three subsequent years and by performing a transplantation experiment with a duration of one year, respectively. Both multiple years and one year of exposure to acidified porewater conditions reduced the number of benthic bacterial operational taxonomic units and invertebrate species diversity by 30–80%. Reduced biodiversity at the vent sites increased the temporal variability in bacterial and nematode community biomass, abundance and composition. While the release from CO2 exposure resulted in a full recovery of nematode species diversity within one year, bacterial diversity remained affected. Overall our findings showed that seawater acidification, induced by seafloor CO2 emissions, was responsible for loss of diversity across different size-classes of benthic organisms, which reduced community stability with potential relapses on ecosystem resilience.

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