Quantitative Analysis of the Topological Structure of Rock Pore Network

Quantitative Analysis of the Topological Structure of Rock Pore Network

As the most significant nonlinear reservoir, the rocks have complex structural characteristic. The pore structure of the rock is varied in shape and complex in connectivity. However, the prevailing methods for characterising the microstructure of rocks, such as the coordination number method and fra...

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Main Authors: Dayu Ye, Guannan Liu, Ning Luo, Feng Gao, Xinmin Zhu, Fengtian Yue
Format: Article
Language:English
Published: Hindawi-Wiley 2021-01-01
Series:Geofluids
Online Access:http://dx.doi.org/10.1155/2021/5517489
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spelling doaj-a2db9c5207ca4df8aa2dc0db2917ce402021-06-28T01:51:06ZengHindawi-WileyGeofluids1468-81232021-01-01202110.1155/2021/5517489Quantitative Analysis of the Topological Structure of Rock Pore NetworkDayu Ye0Guannan Liu1Ning Luo2Feng Gao3Xinmin Zhu4Fengtian Yue5State Key Laboratory for Geomechanics and Deep Underground EngineeringKey Laboratory of Deep Earth Science and Engineering (Sichuan University)State Key Laboratory for Geomechanics and Deep Underground EngineeringState Key Laboratory for Geomechanics and Deep Underground EngineeringState Key Laboratory for Geomechanics and Deep Underground EngineeringMechanics and Civil Engineering InstituteAs the most significant nonlinear reservoir, the rocks have complex structural characteristic. The pore structure of the rock is varied in shape and complex in connectivity. However, the prevailing methods for characterising the microstructure of rocks, such as the coordination number method and fractal theory, are still difficult to quantify the structural properties. In this study, based on the CT-scan method and a new complex network theory, the topological characteristics of rocks such as seepage path selection, degree of pore aggregation, pore importance, and pore module structure are analysed. The results show that the scale-free network model is more reliable in characterising the rock pore network than previously published structural models, and a small number of pores are the “key” to the seepage process. Besides, we proposed a new method to quantify the importance of rock pores and present the distribution characteristics and connectivity laws of the rock-pore network. This provides a new method to study the seepage process of the nonlinear reservoirs.http://dx.doi.org/10.1155/2021/5517489
collection DOAJ
language English
format Article
sources DOAJ
author Dayu Ye
Guannan Liu
Ning Luo
Feng Gao
Xinmin Zhu
Fengtian Yue
spellingShingle Dayu Ye
Guannan Liu
Ning Luo
Feng Gao
Xinmin Zhu
Fengtian Yue
Quantitative Analysis of the Topological Structure of Rock Pore Network
Geofluids
author_facet Dayu Ye
Guannan Liu
Ning Luo
Feng Gao
Xinmin Zhu
Fengtian Yue
author_sort Dayu Ye
title Quantitative Analysis of the Topological Structure of Rock Pore Network
title_short Quantitative Analysis of the Topological Structure of Rock Pore Network
title_full Quantitative Analysis of the Topological Structure of Rock Pore Network
title_fullStr Quantitative Analysis of the Topological Structure of Rock Pore Network
title_full_unstemmed Quantitative Analysis of the Topological Structure of Rock Pore Network
title_sort quantitative analysis of the topological structure of rock pore network
publisher Hindawi-Wiley
series Geofluids
issn 1468-8123
publishDate 2021-01-01
description As the most significant nonlinear reservoir, the rocks have complex structural characteristic. The pore structure of the rock is varied in shape and complex in connectivity. However, the prevailing methods for characterising the microstructure of rocks, such as the coordination number method and fractal theory, are still difficult to quantify the structural properties. In this study, based on the CT-scan method and a new complex network theory, the topological characteristics of rocks such as seepage path selection, degree of pore aggregation, pore importance, and pore module structure are analysed. The results show that the scale-free network model is more reliable in characterising the rock pore network than previously published structural models, and a small number of pores are the “key” to the seepage process. Besides, we proposed a new method to quantify the importance of rock pores and present the distribution characteristics and connectivity laws of the rock-pore network. This provides a new method to study the seepage process of the nonlinear reservoirs.
url http://dx.doi.org/10.1155/2021/5517489
work_keys_str_mv AT dayuye quantitativeanalysisofthetopologicalstructureofrockporenetwork
AT guannanliu quantitativeanalysisofthetopologicalstructureofrockporenetwork
AT ningluo quantitativeanalysisofthetopologicalstructureofrockporenetwork
AT fenggao quantitativeanalysisofthetopologicalstructureofrockporenetwork
AT xinminzhu quantitativeanalysisofthetopologicalstructureofrockporenetwork
AT fengtianyue quantitativeanalysisofthetopologicalstructureofrockporenetwork
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