The atmospheric signature of carbon capture and storage

Citation:
Keeling, RF, Manning AC, Dubey MK.  2011.  The atmospheric signature of carbon capture and storage. Philosophical Transactions of the Royal Society a-Mathematical Physical and Engineering Sciences. 369:2113-2132.

Date Published:

May

Keywords:

air, atmospheric oxygen, box-diffusion, carbon capture and storage, carbon-13, carbon-14, co2, dioxide, general-circulation model, geosequestration, leak detection, o-2, oxygen, sequestration, sinks

Abstract:

Compared with other industrial processes, carbon capture and storage (CCS) will have an unusual impact on atmospheric composition by reducing the CO(2) released from fossil-fuel combustion plants, but not reducing the associated O(2) loss. CO(2) that leaks into the air from below-ground CCS sites will also be unusual in lacking the O(2) deficit normally associated with typical land CO(2) sources, such as from combustion or ecosystem exchanges. CCS may also produce distinct isotopic changes in atmospheric CO(2). Using simple models and calculations, we estimate the impact of CCS or leakage on regional atmospheric composition. We also estimate the possible impact on global atmospheric composition, assuming that the technology is widely adopted. Because of its unique signature, CCS may be especially amenable to monitoring, both regionally and globally, using atmospheric observing systems. Measurements of the O(2)/N(2) ratio and the CO(2) concentration in the proximity of a CCS site may allow detection of point leaks of the order of 1000 ton CO(2) yr(-1) from a CCS reservoir up to 1km from the source. Measurements of O(2)/N(2) and CO(2) in background air from a global network may allow quantification of global and hemispheric capture rates from CCS to the order of +/- 0.4 PgCyr(-1).

Notes:

n/a

Website

DOI:

10.1098/rsta.2011.0016