TY  - JOUR
Y1  - 2019///
PB  - Elsevier B.V.
SN  - 18755100
A1  - Rezk, M.G.
A1  - Foroozesh, J.
JF  - Journal of Natural Gas Science and Engineering
UR  - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85068465402&doi=10.1016%2fj.jngse.2019.102926&partnerID=40&md5=7b7c339256b115570c2f0e6586babc97
VL  - 69
AV  - none
N2  - CO2 sequestration in naturally fractured saline aquifers is important to be studied. This paper investigates the convective-diffusive flow to study CO2 sequestration by dissolution in single and multi-fractured heterogeneous saline aquifers. The effect of fractures density, orientation, permeability, aperture and surface roughness on CO2 dissolution and propagation of density-driven fingers are investigated. The results indicate that a single fracture causes the growing density fingers to deviate towards the high permeability path of the fracture. Additionally, the higher vertical fracture orientation, aperture and permeability will lead to a higher CO2 storage. In the multiple fracture systems, matrix permeability has a dominant and positive effect on CO2 storage. Nevertheless, the effect of fractures properties such as fracture density, spacing, permeability, aperture and surface roughness on the CO2 storage are dependent on the fractures orientation. For instance, having fractures with rough surface can cause CO2 dissolution retardation in the aquifers with only vertical fractures. This study provides more insights into dissolution trapping of CO2 in fractured heterogeneous saline aquifers. © 2019 Elsevier B.V.
N1  - cited By 24
ID  - scholars11367
TI  - Study of convective-diffusive flow during CO2 sequestration in fractured heterogeneous saline aquifers
KW  - Aquifers; Carbon dioxide; Dissolution; Hydrogeology; Surface roughness
KW  -  CO2 sequestration; Density driven flows; Dissolution trapping; Fractured aquifer; High permeability; Matrix permeability; Multiple fracture systems; Vertical fracture
KW  -  Fracture
ER  -