z-logo
Premium
Abandoned well CO 2 leakage mitigation using biologically induced mineralization: current progress and future directions
Author(s) -
Cunningham Alfred B.,
Lauchnor Ellen,
Eldring Joe,
Esposito Richard,
Mitchell Andrew C.,
Gerlach Robin,
Phillips Adrienne J.,
Ebigbo Anozie,
Spangler Lee H.
Publication year - 2013
Publication title -
greenhouse gases: science and technology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.45
H-Index - 32
ISSN - 2152-3878
DOI - 10.1002/ghg.1331
Subject(s) - petroleum engineering , biomineralization , supercritical fluid , leakage (economics) , spark plug , fossil fuel , enhanced oil recovery , materials science , environmental science , geology , chemical engineering , waste management , chemistry , engineering , mechanical engineering , organic chemistry , economics , macroeconomics
Methods of mitigating leakage or re‐plugging abandoned wells before exposure to CO 2 are of high potential interest to prevent leakage of CO 2 injected for geologic carbon sequestration in depleted oil and gas reservoirs where large numbers of abandoned wells are often present. While CO 2 resistant cements and ultrafine cements are being developed, technologies that can be delivered via low viscosity fluids could have significant advantages including the ability to plug small aperture leaks such as fractures or delamination interfaces. Additionally there is the potential to plug rock formation pore space around the wellbore in particularly problematic situations. We are carrying out research on the use of microbial biofilms capable of inducing the precipitation of crystalline calcium carbonate using the process of ureolysis. This method has the potential to reduce well bore permeability, coat cement to reduce CO 2 –related corrosion, and lower the risk of unwanted upward CO 2 migration. In this spotlight, we highlight research currently underway at the Center for Biofilm Engineering (CBE) at Montana State University (MSU) in the area of ureolytic biomineralization sealing for reducing CO 2 leakage risk. This research program combines two novel core testing systems and a 3‐dimensional simulation model to investigate biomineralization under both radial and axial flow conditions and at temperatures and pressures which permit CO 2 to exist in the supercritical state. This combination of modelling and experimentation is ultimately aimed at developing and verifying biomineralization sealing technologies and strategies which can successfully be applied at the field scale for carbon capture and geological storage (CCGS) projects. © 2013 Society of Chemical Industry and John Wiley & Sons, Ltd

This content is not available in your region!

Continue researching here.

Having issues? You can contact us here