Fracture development in shale and its relationship to gas accumulation
Shale with high quartz, feldspar and carbonate, will have low Poisson's ratio, high Young's modulus and high brittleness. As a result, the shale is conducive to produce natural and induced fractures under external forces. In general, there is a good correlation between fracture development in shale...
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| Published in | Di xue qian yuan. Vol. 3; no. 1; pp. 97 - 105 |
|---|---|
| Main Authors | , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
Elsevier B.V
2012
School of Energy, China University of Geosciences, Beijing 100083, China |
| Subjects | |
| Online Access | Get full text |
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| Abstract | Shale with high quartz, feldspar and carbonate, will have low Poisson's ratio, high Young's modulus and high brittleness. As a result, the shale is conducive to produce natural and induced fractures under external forces. In general, there is a good correlation between fracture development in shale and the volume of brittle minerals present. Shale with high TOC or abnormally high pressure has well-developed fractures. Shale fracture development also shows a positive correlation with total gas accumulation and free gas volume, i.e., the better shale fractures are developed, the greater the gas accumulation and therefore the higher the gas production. Fractures provide migration conduits and accumulation spaces for natural gas and formation water, which are favorable for the volumetric increase of free natural gas. Wider fractures in shale result in gas loss. In North America, there is a high success ratio of shale gas exploration and high gas production from high-angle fracture zones in shale. Good natural gas shows or low yield producers in the Lower Paleozoic marine organic matter-rich rocks in the Sichuan Basin are closely related to the degree of fracture development in brittle shales. |
|---|---|
| AbstractList | Shale with high quartz, feldspar and carbonate, will have low Poisson's ratio, high Young's modulus and high brittleness. As a result, the shale is conducive to produce natural and induced fractures under external forces. In general, there is a good correlation between fracture development in shale and the volume of brittle minerals present. Shale with high TOC or abnormally high pressure has well-developed fractures. Shale fracture development also shows a positive correlation with total gas accumulation and free gas volume, i.e., the better shale fractures are developed, the greater the gas accumulation and therefore the higher the gas production. Fractures provide migration conduits and accumulation spaces for natural gas and formation water, which are favorable for the volumetric increase of free natural gas. Wider fractures in shale result in gas loss. In North America, there is a high success ratio of shale gas exploration and high gas production from high-angle fracture zones in shale. Good natural gas shows or low yield producers in the Lower Paleozoic marine organic matter-rich rocks in the Sichuan Basin are closely related to the degree of fracture development in brittle shales. Shale with high quartz, feldspar and carbonate, will have low Poisson's ratio, high Young's modulus and high brittleness. As a result, the shale is conducive to produce natural and induced fractures under external forces. In general, there is a good correlation between fracture development in shale and the volume of brittle minerals present. Shale with high TOC or abnormally high pressure has well-developed fractures. Shale fracture development also shows a positive correlation with total gas accumulation and free gas volume, i.e., the better shale fractures are developed, the greater the gas accumulation and therefore the higher the gas production. Fractures provide migration conduits and accumulation spaces for natural gas and formation water, which are favorable for the volumetric increase of free natural gas. Wider fractures in shale result in gas loss. In North America, there is a high success ratio of shale gas exploration and high gas production from high-angle fracture zones in shale. Good natural gas shows or low yield producers in the Lower Paleozoic marine organic matter-rich rocks in the Sichuan Basin are closely related to the degree of fracture development in brittle shales. P618.13; Shale with high quartz,feldspar and carbonate,will have low Poisson's ratio,high Young's modulus and high brittleness.As a result,the shale is conducive to produce natural and induced fractures under external forces.In general,there is a good correlation between fracture development in shale and the volume of brittle minerals present.Shale with high TOC or abnormally high pressure has well-developed fractures.Shale fracture development also shows a positive correlation with total gas accumulation and free gas volume,i.e.,the better shale fractures are developed,the greater the gas accumulation and therefore the higher the gas production.Fractures provide migration conduits and accumulation spaces for natural gas and formation water,which are favorable for the volumetric increase of free natural gas.Wider fractures in shale result in gas loss.In North America,there is a high success ratio of shale gas exploration and high gas production from high-angle fracture zones in shale.Good natural gas shows or low yield producers in the Lower Paleozoic marine organic matter-rich rocks in the Sichuan Basin are closely related to the degree of fracture development in brittle shales. |
| Author | Wenlong Ding Chao Li Chunyan Li Changchun Xu Kai Jiu Weite Zeng Liming Wu |
| AuthorAffiliation | School of Energy, China University of Geosciences, Beijing 100083, China |
| AuthorAffiliation_xml | – name: School of Energy, China University of Geosciences, Beijing 100083, China |
| Author_xml | – sequence: 1 givenname: Wenlong surname: Ding fullname: Ding, Wenlong email: dingwenlong2006@126.com – sequence: 2 givenname: Chao surname: Li fullname: Li, Chao – sequence: 3 givenname: Chunyan surname: Li fullname: Li, Chunyan – sequence: 4 givenname: Changchun surname: Xu fullname: Xu, Changchun – sequence: 5 givenname: Kai surname: Jiu fullname: Jiu, Kai – sequence: 6 givenname: Weite surname: Zeng fullname: Zeng, Weite – sequence: 7 givenname: Liming surname: Wu fullname: Wu, Liming |
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| Cites_doi | 10.1306/09170404042 10.1306/06190606018 10.1306/031903200184 |
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| Copyright | 2011 Copyright © Wanfang Data Co. Ltd. All Rights Reserved. |
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| Keywords | Gas production Dominant factor Fracture Gas accumulation Shale |
| Language | English |
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| Notes | Shale;Fracture;Dominant factor;Gas accumulation;Gas production 11-5920/P Shale with high quartz, feldspar and carbonate, will have low Poisson's ratio, high Young's modulus and high brittleness. As a result, the shale is conducive to produce natural and induced fractures under external forces. In general, there is a good correlation between fracture development in shale and the volume of brittle minerals present. Shale with high TOC or abnormally high pressure has well-developed fractures. Shale fracture development also shows a positive correlation with total gas accumulation and free gas volume, i.e., the better shale fractures are developed, the greater the gas accumulation and therefore the higher the gas production. Fractures provide migration conduits and accumulation spaces for natural gas and formation water, which are favorable for the volumetric increase of free natural gas. Wider fractures in shale result in gas loss. In North America, there is a high success ratio of shale gas exploration and high gas production from high-angle fracture zones in shale. Good natural gas shows or low yield producers in the Lower Paleozoic marine organic matter-rich rocks in the Sichuan Basin are closely related to the degree of fracture development in brittle shales. ObjectType-Article-2 SourceType-Scholarly Journals-1 ObjectType-Feature-1 content type line 23 |
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| Snippet | Shale with high quartz, feldspar and carbonate, will have low Poisson's ratio, high Young's modulus and high brittleness. As a result, the shale is conducive... Shale with high quartz, feldspar and carbonate, will have low Poisson’s ratio, high Young’s modulus and high brittleness. As a result, the shale is conducive... Shale with high quartz, feldspar and carbonate, will have low Poisson's ratio, high Young's modulus and high brittleness. As a result, the shale is conducive... P618.13; Shale with high quartz,feldspar and carbonate,will have low Poisson's ratio,high Young's modulus and high brittleness.As a result,the shale is... |
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| SubjectTerms | Basins Brittle fracture Correlation Dominant factor Fracture Fracture mechanics Gas accumulation Gas production Natural gas Poissons ratio Quartz Shale 天然气成藏 天然气生产 断裂带 杨氏模量 正相关关系 自由气体 裂缝发育程度 页岩气 |
| Title | Fracture development in shale and its relationship to gas accumulation |
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