Advancing CO2 enhanced oil recovery and storage in unconventional oil play—Experimental studies on Bakken shales

•Pore throat radii in the Bakken shales are tiny, with an average of 3nm.•Organic content in the Bakken shales is measured and characterized by experiments.•CO2 enables extraction of 15–65% hydrocarbons from the Bakken shale samples.•An adsorption isotherm shows that Bakken shales have a strong abil...

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Bibliographic Details
Published in:Applied energy 2017-12, Vol.208 (C), p.171-183
Main Authors: Jin, Lu, Hawthorne, Steven, Sorensen, James, Pekot, Lawrence, Kurz, Bethany, Smith, Steven, Heebink, Loreal, Herdegen, Volker, Bosshart, Nicholas, Torres, José, Dalkhaa, Chantsalmaa, Peterson, Kyle, Gorecki, Charles, Steadman, Edward, Harju, John
Format: Article
Language:English
Subjects:
Bakken shale
Carbon sequestration
CO2 adsorption
Enhanced oil recovery
Supercritical CO2
Unconventional oil
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Summary:•Pore throat radii in the Bakken shales are tiny, with an average of 3nm.•Organic content in the Bakken shales is measured and characterized by experiments.•CO2 enables extraction of 15–65% hydrocarbons from the Bakken shale samples.•An adsorption isotherm shows that Bakken shales have a strong ability to trap CO2.•Carefully tuned numerical models can be used for upscaling the laboratory results. Although well logs and core data show that there is significant oil content in Bakken shales, the oil transport behavior in these source rocks is still not well understood. This lack of understanding impedes the drilling and production operations in the shale members. A series of experiments were conducted to investigate the rock properties of the Bakken shales and how to extract oil from the shales using supercritical CO2. High-pressure mercury injection tests showed that pore throat radii are less than 10nm for most pores in both the upper and lower Bakken samples. Such small pore sizes yield high capillary pressure in the rock and make fluid flow difficult. Total organic carbon content was measured using 180 shale samples, and kerogen was characterized by Rock-Eval pyrolysis, which indicated considerable organic carbon present (10–15wt%) in the shales. However, oil and gas are difficult to mobilize from organic matter using conventional methods. A systematic experimental procedure was carried out to reveal the potential for extracting hydrocarbons from the shale samples using supercritical CO2 under typical Bakken reservoir conditions (e.g., 34.5MPa and 110°C). Results showed that supercritical CO2 enables extraction of a considerable portion (15–65%) of hydrocarbons from the Bakken shales within 24 h. Measurement of CO2 adsorption isotherm showed that Bakken shale has a considerable capability to trap CO2 (up to 17mg/g) under a wide range of pressures. The experimental results suggest the possibility of using supercritical CO2 injection to increase the ultimate oil recovery and store a considerable quantity of CO2 in the Bakken Formation.
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2017.10.054