Produced water integration in CO2 storage using different injection strategies: The effect of salinity on rock petrophysical, mineralogy, wettability and geomechanical properties

Document Type

Article

Publication Date

12-1-2024

Abstract

Optimizing CO2 storage efficiency in Deep saline aquifers (DSA) involves improving each storage trapping mechanism, such as structural/stratigraphy, capillary/residual, mineral, and dissolution trapping mechanisms, while maintaining the reservoir integrity for long-term carbon capture and storage (CCS). These enhancements are driven by a series of geochemical reactions that favorably modify petrophysical, mineralogy, wettability, rock geomechanics of the rock, and dissolution of CO2 in aquifer fluid. Three different CO2 injection strategies have been identified and tested for optimizing CO2 storage and efficiency- Continuous CO2 injection (CCI), Water Alternating Gas (WAG), and Simultaneous scCO2-brine Aquifer Injection (SAI). This study investigates the effect of integrating produced water (PW) into WAG and SAI strategies for CO2 storage, emphasizing how the salinity of the injected water affects reservoir properties alterations in sandstone and limestone formations exposed to scCO2. Experimental results show that high salinity levels accelerate mineralogy changes and wettability alteration, particularly in limestone, leading to porosity, permeability, and mechanical strength changes. While the SAI results showed more aggressive and detrimental changes in rock properties, WAG leads to slower reaction rates, a more stable and effective strategy with more gradual alterations in rock properties due to its ability to balance fluid flow and mechanical strength, hence offering greater stability for long-term CO2 storage. Based on these findings, a 20–50 g/L salinity range is recommended to maintain reservoir integrity and reduce the negative impacts of salinity on CO2 storage efficiency and storage. This study provides valuable insights for optimizing CO2 storage in DSAs, enhancing environmental sustainability, and enhancing mineral trapping through more targeted geochemical reactions and lower changes in rock mechanical strength.

Identifier

85209385274 (Scopus)

Publication Title

Journal of Environmental Management

External Full Text Location

https://doi.org/10.1016/j.jenvman.2024.123307

e-ISSN

10958630

ISSN

03014797

PubMed ID

39571315

Volume

372

Fund Ref

Texas Tech University

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