Comparison of CO<sub>2</sub> and Produced Gas Hydrocarbons to Recover Crude Oil from Williston Basin Shale and Mudrock Cores at 10.3, 17.2, and 34.5 MPa and 110 °C

Hawthorne, Steven B.; Grabanski, Carol B.; Jin, Lu; Bosshart, Nick; Miller, David J.

doi:10.1021/acs.energyfuels.1c00412

Cited by 17 publications

(36 citation statements)

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“…Factors with MMP, Oil Solubility, and the Recovery of Residual Oil from Middle Bakken Rock Samples. The same five gases and Bakken crude oil have previously been used to determine MMP 39 as well as crude oil hydrocarbon solubility 40 and the recovery of residual oil from Bakken rock samples, 41 which was performed by exposing rock cores to each gas at reservoir conditions of 110 °C and 34.5 MPa and collecting the produced oil hydrocarbons for gas chromatographic analysis, as previously described. 22,23 In general, the performance of the five test gases is similar to the results for crude oil swelling shown in Figure 6, that is, propane is superior to ethane, ethane is superior to carbon dioxide and the produced gas, and methane is the least effective.…”

Section: Comparison Of Volumetric Swellingmentioning

confidence: 99%

“…70/20/10 mole fractions) to determine the MMP for each gas with a typical produced oil from the Middle Bakken formation, 39 measure the ability of these gases at different pressures to dissolve Bakken crude oil hydrocarbons, 40 and determine the ability of these gases (again at different pressures) to recover residual oil from both Middle Bakken siltstone and Bakken shale rock samples. 41 These laboratory studies have shown that propane is the superior gas in each of these tests, followed by ethane, then carbon dioxide and the produced gas (which have similar performance), and finally methane as the poorest EOR gas. Propane achieves MMP with Bakken crude oil at the lowest pressure, followed by ethane, carbon dioxide and the produced gas, and finally methane (which requires the highest pressure).…”

Section: Introductionmentioning

confidence: 98%

“…40 Similar trends occur for the recovery of residual crude oil hydrocarbons from Bakken siltstone and source shale samples. 41 While these previous investigations have addressed the relative abilities of carbon dioxide and produced hydrocarbon gases to achieve MMP, dissolve crude oil hydrocarbons, and penetrate and recover residual hydrocarbons from both reservoir and source shale rock samples, the contribution of crude oil swelling with injected gas is also likely to be an important mechanism for successful EOR projects. However, crude oil swelling has not been investigated with carbon dioxide and produced hydrocarbon gases at temperature and pressures relevant to the Bakken Petroleum System.…”

Section: Introductionmentioning

confidence: 99%

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Volumetric Swelling of Bakken Crude Oil with Carbon Dioxide and Hydrocarbon Gases at 110 °C and Pressures of up to 34.5 Megapascals

2022

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Volumetric swelling tests were performed using a typical crude oil produced from the Middle Bakken formation to compare the ability of pure carbon dioxide, methane, ethane, propane, and a typical Bakken produced gas (ca. 68/22/10 mole fraction methane/ethane/propane) at the reservoir temperature (110 °C) and pressures of up to 34.5 MPa (5000 psi). Crude oil swelling factors at 34.5 MPa for the individual hydrocarbon gases were quite low for methane (1.13), moderately higher for the produced gas (1.39), and much higher for ethane (2.50). Propane caused dramatically higher crude oil swelling than any of the test gases and reached a volumetric expansion of 2.6 at 4.2 MPa (the highest degree of swelling that could be observed in the test cell). The presence of water had no significant effect on oil swelling for the hydrocarbon gases. However, carbon dioxide showed a moderate increase in oil swelling at higher pressures when water was present in the high-pressure cell and achieved oil swelling factors at 34.5 MPa of 1.60 with water and 1.42 without water. The crude oil swelling results show the same trend as that of the individual gas' solubility in the crude oil. The oil swelling results were compared to earlier experimental results that used the same injected gases, temperature, and pressure ranges to determine each gas' minimum miscibility pressure (MMP) and ability to dissolve oil hydrocarbons with the same crude oil as was used in the swelling tests, as well as the ability of the same test gases to recover residual oil from siltstone samples collected from the Middle Bakken target drilling zone. Oil swelling, MMP, crude oil solubility in each gas, and residual oil recovery tests all showed that propane is the superior EOR fluid, followed by ethane, then carbon dioxide and the produced gas (which are similar), and finally methane, which is the poorest in each lab test of the five gases investigated.

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Section: Comparison Of Volumetric Swellingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

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Volumetric Swelling of Bakken Crude Oil with Carbon Dioxide and Hydrocarbon Gases at 110 °C and Pressures of up to 34.5 Megapascals

2022

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“…One strategy for producing oil from already-fractured shale wells involves injecting oil-miscible gases such as CO 2 , ethane, propane, nitrogen, or natural gas to extract the remaining oil. − Of all the gases tested, CO 2 has demonstrated several advantages. CO 2 increases oil extraction by a variety of mechanisms including diffusion, vaporization, oil swelling, oil viscosity reduction, pressure support, CO 2 –oil interfacial tension (IFT) reduction, solution gas drive, and relative permeability hysteresis .…”

Section: Introductionmentioning

confidence: 99%

Dissolving Nonionic Surfactants in CO₂ to Improve Oil Recovery in Unconventional Reservoirs via Wettability Alteration

et al. 2022

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CO2 injection is a promising method for enhanced oil recovery (EOR) in unconventional shale reservoirs. In this work, we postulate that CO2 EOR may be improved by the dissolution of surfactants into CO2. Although CO2 is a relatively good solvent for oil, we show that CO2 and Eagle Ford oil are immiscible at compositions above 70 wt % CO2, even at pressures as high as 62 MPa. The presence of a CO2–oil interface at reservoir conditions indicates that the addition of a surfactant has the potential to improve oil recoveryvia wettability alteration from oil-wet to CO2-wet, CO2–oil interfacial tension (IFT) reduction, or both. Three nonionic surfactants (branched tridecyl ethoxylate Indorama SURFONIC TDA-9, branched nonylphenol ethoxylate Indorama SURFONIC N-100, and linear dodecyl ethoxylate Indorama SURFONIC L12-6) were evaluated for CO2-solubility, shale wettability alteration, effect on CO2–oil IFT, ability to generate CO2–oil foams, and ability to increase oil extraction from Eagle Ford, Mancos, and Bakken shale cores. Each surfactant dissolved in CO2 up to 1 wt % at pressures and temperatures commensurate with CO2 EOR. CO2-dissolved surfactants did not significantly affect CO2–oil IFT or generate CO2–oil foams, but they did induce a dramatic change in the contact angle of an oil droplet on an oil-aged shale chip in CO2 from strongly oil-wet (11°) toward intermediate CO2–oil wettability (82°) (at 80 °C, 27.6 MPa). The branched tridecyl ethoxylated surfactant, SURFONIC TDA-9, afforded the highest oil recovery in core soaking experiments75%, compared to 71% by pure CO2. Analysis of oil extracts by gas chromatography revealed that heavier oil components were produced when the surfactant was added to CO2. These results indicate that CO2-dissolved surfactants may increase oil recovery from shale by wettability alteration from oil-wet toward CO2-wet.

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“…One of the most convenient methods of utilizing this gas is to reinject it back into the reservoir as an EOR agent . Using hydrocarbon gas as an EOR agent in huff-and-puff mode could be effective in shale deposits ,, given the presence of natural fractures. ,, The efficiency of this method depends entirely on the minimum miscibility pressure (MMP) at which the associated gas achieves miscibility with the reservoir oil. Miscibility causes oil swelling and a decrease in oil viscosity.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Oil Recovery Method Selection for Shale Oil Based on Numerical Simulations

et al. 2021

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As unconventional reserves, oil shale deposits require additional oil recovery techniques to achieve favorable production levels. The efficiency of a shale reservoir development project is highly dependent on the application of enhanced oil recovery (EOR) techniques. There are many studies devoted to discrete investigations of each EOR method. Most of them claim that one particular method is particularly effective in increasing oil recovery. Despite the wealth of such research, it remains hard to say with certainty which technique would be the most effective when applied in the extraction of unconventional reserves. In this work, we aim to answer this question by means of a comparative study. Three EOR methods were applied and analyzed in the same environment, a single target objectan oil field in Western Siberia characterized by ultra-low permeability (0.03 mD on average) and high organic content. Methods involving huff-and-puff injection of a surfactant solution, hydrocarbon gas, and hot water were studied using numerical reservoir simulations based on preceding laboratory experiments. A single horizontal well having undergone nine-stage hydraulic fracturing was used as the field site model. The comparative calculations of cumulative oil production over an 8-year period revealed that the injection of hot (supercritical) water led to the highest oil recovery in the target shale reservoir. Each EOR method was implemented using the best operation scenario. All three cases resulted in an increase in cumulative oil production compared to the depletion mode, though the efficiency was distinctly different. Twenty-six percent more oil was obtained after hot water injection, 16% after hydrocarbon gas, and 12% after a surfactant solution. Simulation of a hot water huff-and-puff operation over a longer period (43 years) led to a level of oil production 3 times higher than depletion. The drawbacks of each EOR method on the shale site are discussed in the results. A possible solution was proposed for preventing the negative effects of heat loss and water blockage incurred from hot water injection. The comparative study concludes that hot water injection should lead to the highest volume of oil recovery. The conclusions drawn are suggested to be relevant for similar shale fields.

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Comparison of CO₂ and Produced Gas Hydrocarbons to Recover Crude Oil from Williston Basin Shale and Mudrock Cores at 10.3, 17.2, and 34.5 MPa and 110 °C

Cited by 17 publications

References 71 publications

Volumetric Swelling of Bakken Crude Oil with Carbon Dioxide and Hydrocarbon Gases at 110 °C and Pressures of up to 34.5 Megapascals

Volumetric Swelling of Bakken Crude Oil with Carbon Dioxide and Hydrocarbon Gases at 110 °C and Pressures of up to 34.5 Megapascals

Dissolving Nonionic Surfactants in CO₂ to Improve Oil Recovery in Unconventional Reservoirs via Wettability Alteration

Enhanced Oil Recovery Method Selection for Shale Oil Based on Numerical Simulations

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Comparison of CO2 and Produced Gas Hydrocarbons to Recover Crude Oil from Williston Basin Shale and Mudrock Cores at 10.3, 17.2, and 34.5 MPa and 110 °C

Cited by 17 publications

References 71 publications

Volumetric Swelling of Bakken Crude Oil with Carbon Dioxide and Hydrocarbon Gases at 110 °C and Pressures of up to 34.5 Megapascals

Volumetric Swelling of Bakken Crude Oil with Carbon Dioxide and Hydrocarbon Gases at 110 °C and Pressures of up to 34.5 Megapascals

Dissolving Nonionic Surfactants in CO2 to Improve Oil Recovery in Unconventional Reservoirs via Wettability Alteration

Enhanced Oil Recovery Method Selection for Shale Oil Based on Numerical Simulations

Contact Info

Product

Resources

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Comparison of CO₂ and Produced Gas Hydrocarbons to Recover Crude Oil from Williston Basin Shale and Mudrock Cores at 10.3, 17.2, and 34.5 MPa and 110 °C

Dissolving Nonionic Surfactants in CO₂ to Improve Oil Recovery in Unconventional Reservoirs via Wettability Alteration