Effect of Aquifer Anisotropy, Brine Withdrawal, and Well Completion Strategy on CO₂ Injectivity in Shallow Saline Aquifer

Author

Olanrewaju M. Tiamiyu
Runar Nygaard, Missouri University of Science and TechnologyFollow
Baojun Bai, Missouri University of Science and TechnologyFollow

Abstract

The most promising near term solution to reduce CO₂ emissions is to capture the CO₂ produced from coal and gas fired power plants and inject it into deeply buried saline aquifers. However a large amount of these plants are far away from deep sedimentary basins and therefore alternative solutions have to be sought. Detailed computer simulation, using compositional numerical model software CMG-GEMGHG, was used to study the effects of aquifer anisotropy (heterogeneity), well completion technique (perforation and well orientation), brine production and injection rates on CO₂ injectivity, and capability to retain and store reasonably large amount of CO₂ for an extended period of time. The objective of this study is to find the optimal combination of operational parameters (injection rates, well completion techniques and brine withdrawal strategy), and how the interplay of these parameters with aquifer anisotropy (heterogeneity) affects, and can be manipulated to optimally harness CO₂ storage potential and leakage risk mitigation in shallow saline aquifers.

Injected CO₂ exists in three main forms in the aquifer, supercritical, dissolved and aqueous forms with amount depending largely on prevailing formation pressure and the depth of well placement. Without brine withdrawal, horizontal injector wells with the vertical sections closed have higher CO₂ injectivity compared to vertical and deviated wells with bottom half perforated. With brine withdrawal more CO₂ was injected and anisotropy (heterogeneity) (K_v/K_h ratio) has significant effect on CO₂ injectivity, but well perforation and orientation has negligible effect, except for an extended (85 years) injection period when aquifer pressure has reached the maximum allowable. The impact of anisotropy (heterogeneity) on CO₂ injectivity was observed to decrease with increase on injection rate for injection well placed in uppermost layers. This study shows CO₂ sequestration in shallow saline aquifer has significant potential. Results from this study can potentially provide guideline for well completion technique, injection rate and brine withdrawal strategy, depending on aquifer properties, that can be applied in CO₂ sequestration in shallow saline aquifer.

Recommended Citation

O. M. Tiamiyu et al., "Effect of Aquifer Anisotropy, Brine Withdrawal, and Well Completion Strategy on CO₂ Injectivity in Shallow Saline Aquifer," Proceedings of the SPE International Conference on CO2 Capture, Storage, and Utilization (2010, New Orleans, LA), pp. 285 - 299, Society of Petroleum Engineers (SPE), Nov 2010.

The definitive version is available at https://doi.org/10.2118/139583-MS

Meeting Name

SPE International Conference on CO2 Capture, Storage, and Utilization (2010: Nov. 10-12, New Orleans, LA)

Department(s)

Geosciences and Geological and Petroleum Engineering

Keywords and Phrases

Aquifer Properties; Coal And Gas Fired Power Plants; Deviated Wells; Formation Pressure; Horizontal Injectors; Injection Period; Injection Rates; Injection Wells; Injectivity; Numerical Models; Operational Parameters; Optimal Combination; Risk Mitigation; Saline Aquifers; Sedimentary Basin; Storage Potential; Super-Critical; Vertical Section; Well Orientation; Well Placement

International Standard Book Number (ISBN)

978-1617820830

Document Type

Article - Conference proceedings

Document Version

Citation

File Type

text

Language(s)

English

Rights

© 2010 Society of Petroleum Engineers (SPE), All rights reserved.

Publication Date

01 Nov 2010