Genetic Types and Main Control Factors of Microfractures in Tight Oil Reservoirs of Jimsar Sag

Genetic Types and Main Control Factors of Microfractures in Tight Oil Reservoirs of Jimsar Sag

Microfractures are key for migrating and aggregating hydrocarbon source rocks and fracturing oil-gas exploitation in tight reservoirs. In this study, rock samples from the Lucaogou Formation tight reservoirs in Xinjiang, China, were studied using multidisciplinary techniques to investigate the genet...

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Main Authors: Xiangye Kong, Jianhui Zeng, Xianfeng Tan, Haowei Yuan, Dan Liu, Qun Luo, Qianyou Wang, Rusi Zuo
Format: Article
Language:English
Published: Hindawi-Wiley 2021-01-01
Series:Geofluids
Online Access:http://dx.doi.org/10.1155/2021/5558551
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spelling doaj-359ace2bad554d8db9afc68baae547552021-08-02T00:00:56ZengHindawi-WileyGeofluids1468-81232021-01-01202110.1155/2021/5558551Genetic Types and Main Control Factors of Microfractures in Tight Oil Reservoirs of Jimsar SagXiangye Kong0Jianhui Zeng1Xianfeng Tan2Haowei Yuan3Dan Liu4Qun Luo5Qianyou Wang6Rusi Zuo7College of GeosciencesCollege of GeosciencesCollege of Petroleum and Gas EngineeringCollege of GeosciencesInstitute of Exploration TechniquesUnconventional Natural Gas InstituteDepartment of EarthState Key Laboratory of Marine GeologyMicrofractures are key for migrating and aggregating hydrocarbon source rocks and fracturing oil-gas exploitation in tight reservoirs. In this study, rock samples from the Lucaogou Formation tight reservoirs in Xinjiang, China, were studied using multidisciplinary techniques to investigate the genetic types and main control factors of microfractures. Results indicated that the Lucaogou Formation mainly developed diagenetic microfractures followed by tectonic microfractures, with slight formations of granular microfractures. These observations were used to clarify the relationship between the development of microfractures and the pore fluid content, lithology, mineral composition, and stratum thickness. A higher pore fluid content corresponded to a lower compressive strength of the rocks and a larger ring count, resulting in a higher probability of failure and microfracture formation. Tight reservoirs containing more quartz and carbonate minerals were found to develop more microfractures. Quartz grains showed fractures at the margins under stress, which increased the pore permeability of rocks. Carbonate minerals tended to form microfractures owing to corrosion. Microfracture formation mechanisms differed depending on lithology, and microfractures were found to develop most in dolomite and dolomitic siltstones and least in mudstone. Muddy rocks developed fewer tectonic fractures because they can easily absorb stress and undergo plastic deformation. Within a certain stratum thickness range, the average single-well fracture space and stratum thickness showed positive correlations. Moreover, the fracture space increased and the fracture density decreased as the stratum thickness increased. When the stratum thickness was less than 2.5 m, the fracture space increased linearly with the stratum thickness, and when the stratum thickness was greater than 2.5 m, the fracture space remained constant. This study will provide an essential scientific basis for enhancing tight oil recovery.http://dx.doi.org/10.1155/2021/5558551
collection DOAJ
language English
format Article
sources DOAJ
author Xiangye Kong
Jianhui Zeng
Xianfeng Tan
Haowei Yuan
Dan Liu
Qun Luo
Qianyou Wang
Rusi Zuo
spellingShingle Xiangye Kong
Jianhui Zeng
Xianfeng Tan
Haowei Yuan
Dan Liu
Qun Luo
Qianyou Wang
Rusi Zuo
Genetic Types and Main Control Factors of Microfractures in Tight Oil Reservoirs of Jimsar Sag
Geofluids
author_facet Xiangye Kong
Jianhui Zeng
Xianfeng Tan
Haowei Yuan
Dan Liu
Qun Luo
Qianyou Wang
Rusi Zuo
author_sort Xiangye Kong
title Genetic Types and Main Control Factors of Microfractures in Tight Oil Reservoirs of Jimsar Sag
title_short Genetic Types and Main Control Factors of Microfractures in Tight Oil Reservoirs of Jimsar Sag
title_full Genetic Types and Main Control Factors of Microfractures in Tight Oil Reservoirs of Jimsar Sag
title_fullStr Genetic Types and Main Control Factors of Microfractures in Tight Oil Reservoirs of Jimsar Sag
title_full_unstemmed Genetic Types and Main Control Factors of Microfractures in Tight Oil Reservoirs of Jimsar Sag
title_sort genetic types and main control factors of microfractures in tight oil reservoirs of jimsar sag
publisher Hindawi-Wiley
series Geofluids
issn 1468-8123
publishDate 2021-01-01
description Microfractures are key for migrating and aggregating hydrocarbon source rocks and fracturing oil-gas exploitation in tight reservoirs. In this study, rock samples from the Lucaogou Formation tight reservoirs in Xinjiang, China, were studied using multidisciplinary techniques to investigate the genetic types and main control factors of microfractures. Results indicated that the Lucaogou Formation mainly developed diagenetic microfractures followed by tectonic microfractures, with slight formations of granular microfractures. These observations were used to clarify the relationship between the development of microfractures and the pore fluid content, lithology, mineral composition, and stratum thickness. A higher pore fluid content corresponded to a lower compressive strength of the rocks and a larger ring count, resulting in a higher probability of failure and microfracture formation. Tight reservoirs containing more quartz and carbonate minerals were found to develop more microfractures. Quartz grains showed fractures at the margins under stress, which increased the pore permeability of rocks. Carbonate minerals tended to form microfractures owing to corrosion. Microfracture formation mechanisms differed depending on lithology, and microfractures were found to develop most in dolomite and dolomitic siltstones and least in mudstone. Muddy rocks developed fewer tectonic fractures because they can easily absorb stress and undergo plastic deformation. Within a certain stratum thickness range, the average single-well fracture space and stratum thickness showed positive correlations. Moreover, the fracture space increased and the fracture density decreased as the stratum thickness increased. When the stratum thickness was less than 2.5 m, the fracture space increased linearly with the stratum thickness, and when the stratum thickness was greater than 2.5 m, the fracture space remained constant. This study will provide an essential scientific basis for enhancing tight oil recovery.
url http://dx.doi.org/10.1155/2021/5558551
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