Multi-Isothermal Stage Pyrolysis of the Chang 7<sub>3</sub> Shale Oil Reservoirs, Ordos Basin: Implications for Oil Occurrence States and In Situ Conversion Exploitation

Guo, Ruiliang; Li, Shixiang; Zhou, Xinping; Guo, Qiheng; Li, Shutong; Zhang, Jiaqiang; Hao, Lewei; Ma, Xiaofeng; Qiu, Junli; Wang, Yan; Liu, Peng

doi:10.1021/acsearthspacechem.2c00057

Cited by 5 publications

(3 citation statements)

References 55 publications

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“…In general, petroleum with a higher API gravity contains more light components. Studies employing TD‐GC–MS/FID have demonstrated that shale products evaporated at relatively lower temperatures have significantly fewer carbon atoms and lower molecular weight (Abrams et al, 2017; Guo et al, 2022; Jiang, Li, et al, 2016; Romero‐Sarmiento, Euzen, et al, 2016). To assess the proportions of different pyrolysis fractions in the shale samples, Oil‐1, Oil‐2, Oil‐3, and Oil‐4 obtained through multi‐step programmed pyrolysis were normalized and expressed as percentages (P Oil‐1 , P Oil‐2 , P Oil‐3 , and P Oil‐4 ) (Table 2).…”

Section: Discussionmentioning

confidence: 99%

“…Multi-step pyrolysis divides the temperature range below 300 or 350 C into multiple heating and isothermal intervals to obtain the more easily volatilized petroleum content in shale, often referred to as the free (movable) fraction (Beti & Ring, 2019;Maende et al, 2017;Romero-Sarmiento, Euzen, et al, 2016;Romero-Sarmiento, Pillot, et al, 2016). Monitoring the pyrolysis products in different temperature intervals using thermal desorption-gas chromatography-mass spectrometry/flame ionization detection (TD-GC-MS/FID) technology confirms that the pyrolysis products in the low-temperature range have relatively smaller molecular weights (Abrams et al, 2017;Guo et al, 2022;Jiang, Li, et al, 2016;Romero-Sarmiento, Euzen, et al, 2016). However, concerns arise regarding whether the pyrolysis products from this range can accurately represent the content of free (movable) oil, given the challenge of kerogen adsorption in the low-temperature range (Abrams et al, 2017;Feng et al, 2021;Romero-Sarmiento, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Impact of petroleum expulsion and evaporation losses on shale oil assessment using pyrolysis techniques

You,

Liu,

Song

et al. 2023

Geological Journal

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Shale reservoirs contain petroleum that undergoes losses through oil expulsion and evaporation, with uncertain implications on shale oil reserves and mobility evaluation. This study focuses on understanding the influence of these losses on open‐system pyrolysis, the primary method for assessing shale oil content and mobility. Comprehensive analyses were performed on 26 lacustrine shale samples from the Chang7 Member, encompassing total organic carbon (TOC), programmed pyrolysis, solvent extraction, and gas chromatography–mass spectrometry (GC–MS). The research examines the impact of petroleum losses on petroleum fractions, the oil saturation index (OSI), and multi‐step pyrolysis outcomes. The findings indicate that Chang7 shale with TOC content above 7% experiences more substantial petroleum losses than those with TOC below 7%. Petroleum losses result in significant fractional distillation of crude oil in the shale, leading to the deterioration of shale oil properties and a notable reduction in free oil content in S1, ultimately causing a decline in OSI values. As a result, Chang7 shale with TOC below 7% demonstrates a higher potential for shale oil recovery, whereas Chang7 shale with TOC exceeding 7% should be considered more significant as a hydrocarbon source rock. Moreover, multi‐step pyrolysis is not suitable for assessing petroleum mobility in shale with low free oil content (OSI values below 100 mg/g). This limitation arises from the loss of free low‐boiling components in Chang7 shale, and the currently detected low‐boiling pyrolysis products may predominantly exist in an adsorbed state.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Impact of petroleum expulsion and evaporation losses on shale oil assessment using pyrolysis techniques

You,

Liu,

Song

et al. 2023

Geological Journal

Self Cite

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“…Shale oil and gas, as the most potential strategic replacement resources, are also hot spots for exploration and development in the global oil field in recent years [1][2][3][4][5] fracturing technology has become an essential method to develop shale oil and gas effectively [6][7][8]. Hydraulic fracturing forms artificial fractures in the shale, accompanied by the intrusion of fracturing fluids into the shale matrix.…”

Section: Introductionmentioning

confidence: 99%

Investigation of the Effect of Fracturing Fluids on Shale Pore Structure by Nuclear Magnetic Resonance

Zhu,

Wang,

You

et al. 2023

Minerals

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Hydraulic fracturing technology significantly enhances the productivity of shale oil and gas reservoirs. Nonetheless, the infiltration of fracturing fluid into shale formations can detrimentally affect the microscopic pore structure, thereby impairing the efficacy of hydraulic stimulation. In this study, nuclear magnetic resonance (NMR) technology was utilized to conduct high-pressure soaking tests on shale specimens treated with EM30+ + guar gum mixed water and CNI nano variable-viscosity slickwater, where various concentrations of a drag reducer were utilized. Additionally, the differences in porosity, permeability, mineral composition, and iron ion concentration before and after the measurements were compared, which were used to analyze the influence on the shale’s microscopic pore structure. It features a reduction in the total pore volume after the interaction with the fracturing fluid, with the pore-throat damage degree, porosity damage degree, and permeability damage degree ranging from 0.63% to 5.62%, 1.51% to 6.84%, and 4.17% to 19.61%, respectively. Notably, EM30+ + guar gum mixed water exhibits heightened adsorption retention, alkaline dissolution, and precipitation compared to CNI nano variable-viscosity slickwater, rendering it more deleterious to shale. Moreover, higher concentrations of drag reducers, such as EM30+ or CNI-B, predominantly result in damage to the shale’s micropores. Shale compositions characterized by lower content of quartz and elevated proportions of clay minerals and iron-bearing minerals showcase augmented mineral dissolution and precipitation, consequently intensifying the shale damage. The hydration expansion of mixed-layer illite/smectite profoundly diminishes the core permeability. Consequently, the mechanisms underpinning the damage inflicted on shale’s microscopic pore structure primarily involve fracturing fluid adsorption and retention, mineral dissolution, and precipitation, such as clay minerals and iron-containing minerals.

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Oil–Source Correlation and Secondary Migration Paths in the Triassic Chang 10 of the Yanchang Formation in the Zhidan Area, Ordos Basin, China: Evidence from Biomarkers, Rare Earth Elements, and Carbazole Signatures

Deng

Chu

et al. 2023

Nat Resour Res

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Multi-Isothermal Stage Pyrolysis of the Chang 7₃ Shale Oil Reservoirs, Ordos Basin: Implications for Oil Occurrence States and In Situ Conversion Exploitation

Cited by 5 publications

References 55 publications

Impact of petroleum expulsion and evaporation losses on shale oil assessment using pyrolysis techniques

Impact of petroleum expulsion and evaporation losses on shale oil assessment using pyrolysis techniques

Investigation of the Effect of Fracturing Fluids on Shale Pore Structure by Nuclear Magnetic Resonance

Oil–Source Correlation and Secondary Migration Paths in the Triassic Chang 10 of the Yanchang Formation in the Zhidan Area, Ordos Basin, China: Evidence from Biomarkers, Rare Earth Elements, and Carbazole Signatures

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Multi-Isothermal Stage Pyrolysis of the Chang 73 Shale Oil Reservoirs, Ordos Basin: Implications for Oil Occurrence States and In Situ Conversion Exploitation

Cited by 5 publications

References 55 publications

Impact of petroleum expulsion and evaporation losses on shale oil assessment using pyrolysis techniques

Impact of petroleum expulsion and evaporation losses on shale oil assessment using pyrolysis techniques

Investigation of the Effect of Fracturing Fluids on Shale Pore Structure by Nuclear Magnetic Resonance

Oil–Source Correlation and Secondary Migration Paths in the Triassic Chang 10 of the Yanchang Formation in the Zhidan Area, Ordos Basin, China: Evidence from Biomarkers, Rare Earth Elements, and Carbazole Signatures

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Multi-Isothermal Stage Pyrolysis of the Chang 7₃ Shale Oil Reservoirs, Ordos Basin: Implications for Oil Occurrence States and In Situ Conversion Exploitation