The physical characteristics of a CO 2 seeping fault: the implications of fracture permeability for carbon capture and storage integrity
Bond, Clare E.; Kremer, Yannick; Johnson, Gareth; Hicks, Nigel; Lister, Robert; Jones, Dave G.; Haszeldine, R. Stuart; Saunders, Ian; Gilfillan, Stuart M.V.; Shipton, Zoe K.; Pearce, Jonathan. 2017 The physical characteristics of a CO 2 seeping fault: the implications of fracture permeability for carbon capture and storage integrity. International Journal of Greenhouse Gas Control, 61. 49-60. 10.1016/j.ijggc.2017.01.015
Before downloading, please read NORA policies.Preview |
Text
Bond-et-al-JGGC-accepted-reduced2017.pdf - Accepted Version Available under License Creative Commons Attribution Non-commercial No Derivatives 4.0. Download (5MB) | Preview |
Abstract/Summary
To ensure the effective long-term storage of CO2 in candidate geological storage sites, evaluation of potential leakage pathways to the surface should be undertaken. Here we use a series of natural CO2 seeps along a fault in South Africa to assess the controls on CO2 leakage to the surface. Geological mapping and detailed photogrammetry reveals extensive fracturing along the mapped fault trace. Measurements of gas flux and CO2 concentration across the fracture corridor give maximum soil gas measurements of 27% CO2 concentration and a flux of 191 g m−2 d−1. These measurements along with observations of gas bubbles in streams and travertine cones attest to CO2 migration to the surface. Permeability measurements on the host rock units show that the tillite should act as an impermeable seal to upward CO2 migration. The combined permeability and fracture mapping data indicate that fracture permeability creates the likely pathway for CO2 migration through the low permeability tillite to the surface. Heterogeneity in fracture connectivity and intensity at a range of scales will create local higher permeability pathways along the fracture corridor, although these may seal with time due to fluid-rock interaction. The results have implications for the assessment and choice of geological CO2 storage sites, particularly in the assessment of sub-seismic fracture networks.
Item Type: | Publication - Article |
---|---|
Digital Object Identifier (DOI): | 10.1016/j.ijggc.2017.01.015 |
ISSN: | 17505836 |
Date made live: | 15 Aug 2017 13:57 +0 (UTC) |
URI: | https://nora.nerc.ac.uk/id/eprint/517583 |
Actions (login required)
View Item |
Document Downloads
Downloads for past 30 days
Downloads per month over past year