Preprints
https://doi.org/10.5194/bgd-12-8909-2015
https://doi.org/10.5194/bgd-12-8909-2015
16 Jun 2015
 | 16 Jun 2015
Status: this preprint was under review for the journal BG but the revision was not accepted.

Reviews and synthesis: Carbon capture and storage monitoring – an integrated biological, biophysical and chemical approach

N. Hicks, U. Vik, P. Taylor, E. Ladoukakis, J. Park, F. Kolisis, H. Stahl, and K. S. Jakobsen

Abstract. Carbon capture and storage (CCS) is a developing technology that seeks to mitigate against the impact of increasing anthropogenic carbon dioxide (CO2) production by capturing CO2 from large point source emitters. After capture the CO2 is compressed and transported to a reservoir where it is stored for geological time scales. Potential leakages from CCS projects, where stored CO2 migrates through the overlaying sediments, are likely to have severe implications on benthic and marine ecosystems. Nonetheless, prokaryotic response to elevated CO2 concentrations has been suggested as one of the first detectable warnings if a CO2 leakage should occur. Applying properties of prokaryotic communities (i.e. community composition and metabolic status) as a novel CO2 monitoring application is highly reliable within a multidisciplinary framework, where deviations from the baseline can easily be identified.

In this paper we review current knowledge about the impact of CO2 leakages on marine sediments from a multidisciplinary-based monitoring perspective. We focus on aspects from the fields of biology, geophysics, and chemistry, and discuss a case study example. We argue the importance of an integrative multidisciplinary approach, incorporating biogeochemistry, geophysics, microbial ecology and modelling, with a particular emphasis on metagenomic techniques and novel bioinformatics, for future CCS monitoring. Within this framework, we consider that an effective CCS monitoring programme will ensure that large-scale leakages with potentially devastating effects for the overlaying ecosystem are avoided. Furthermore, the multidisciplinary approach suggested here for CCS monitoring is generic, and can be adapted to other systems of interest.

Publisher's note: Copernicus Publications remains neutral with regard to jurisdictional claims made in the text, published maps, institutional affiliations, or any other geographical representation in this preprint. The responsibility to include appropriate place names lies with the authors.
N. Hicks, U. Vik, P. Taylor, E. Ladoukakis, J. Park, F. Kolisis, H. Stahl, and K. S. Jakobsen
 
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Status: closed
AC: Author comment | RC: Referee comment | SC: Short comment | EC: Editor comment
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Status: closed
Status: closed
AC: Author comment | RC: Referee comment | SC: Short comment | EC: Editor comment
Printer-friendly Version - Printer-friendly version Supplement - Supplement
N. Hicks, U. Vik, P. Taylor, E. Ladoukakis, J. Park, F. Kolisis, H. Stahl, and K. S. Jakobsen
N. Hicks, U. Vik, P. Taylor, E. Ladoukakis, J. Park, F. Kolisis, H. Stahl, and K. S. Jakobsen

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Short summary
Here we review current knowledge about the impact of CO2 leaks from marine carbon capture storage sites, and use a recent case study to assess current monitoring techniques. We integrate aspects of microbiology, geophysics, chemistry and bioinformatics to suggest a future integrative monitoring technique, using metagenomics, to prevent large-scale leakages and associated consequences. This novel approach is generic and can be adapted to other systems of interest for environmental monitoring.
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