Evolution of fracture network, permeability and induced seismicity during fatigue hydraulic fracturing

IF 7.5 1区工程技术 Q1 ENGINEERING, GEOLOGICAL

International Journal of Rock Mechanics and Mining Sciences Pub Date : 2025-10-06 DOI:10.1016/j.ijrmms.2025.106297

Chang Xia , Huanyu Wu , Ki-Bok Min , Derek Elsworth , Qi Zhao

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引用次数: 0

Abstract

Cyclic hydraulic fracturing (CHF) shows potential in reducing induced seismicity compared to conventional hydraulic fracturing (HF). However, controlling mechanisms that potentially limit induced seismicity but still enhance permeability during CHF remain unclear. We develop a novel time- and stress-dependent damage representative of fatigue crack growth through a coupled hydromechanical model using the block-based discrete element method (DEM). This new framework addresses the challenges in modeling CHF by simultaneously considering discrete fracture network, hydromechanical coupling, fatigue and in-situ stresses. Matching pressurization cycles-to-failure data in laboratory experiments confirms the contribution of sub-critical crack growth in the reduced breakdown pressures in CHF. Modeling fluid injections into a fractured reservoir with contrasting far-field stress ratios of 1.17 and 1.40 shows that CHF mainshocks are smaller than those by conventional HF. While HF induces seismicity primarily through the creation of new fractures, CHF generates seismicity predominantly from multiple small shear reactivations – these dissipate energy progressively and thereby reduce mainshock magnitude. CHF enhances permeability by creating a more connected fracture network than HF. Far-field stress ratio influences permeability by directing fracture growth orientations, and larger stress ratio leads to a higher proportion of shear fractures. This study provides new quantitative insights into the mechanisms of CHF in reducing induced seismicity while increasing effectiveness in elevating permeability.

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疲劳水力压裂裂缝网络演化、渗透率及诱发地震活动性

与常规水力压裂（HF）相比，循环水力压裂（CHF）在减少诱发地震活动方面具有潜力。然而，在CHF期间，潜在限制诱发地震活动性但仍能提高渗透率的控制机制尚不清楚。本文采用基于块的离散元法（DEM）建立了一个耦合的流体力学模型，建立了一种新的疲劳裂纹扩展的时间和应力相关损伤模型。这个新框架通过同时考虑离散裂缝网络、流体力学耦合、疲劳和地应力，解决了CHF建模的挑战。实验室实验中匹配的加压循环到失效数据证实了亚临界裂纹扩展对CHF中降低的破裂压力的贡献。在远场应力比为1.17和1.40的情况下，对裂缝性储层进行流体注入模拟表明，CHF主震比常规HF主震小。高频主要通过新裂缝的产生引起地震活动，而高频主要通过多次小剪切再激活引起地震活动，这些活动逐渐耗散能量，从而降低了主震震级。与HF相比，CHF通过创建更紧密的裂缝网络来提高渗透率。远场应力比通过引导裂缝生长方向影响渗透率，应力比越大，剪切裂缝比例越高。该研究为CHF在降低诱发地震活动性的同时提高渗透率的有效性的机制提供了新的定量见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Rock Mechanics and Mining Sciences 工程技术-工程：地质

CiteScore

14.00

自引率

5.60%

发文量

196

审稿时长

18 weeks

期刊介绍： The International Journal of Rock Mechanics and Mining Sciences focuses on original research, new developments, site measurements, and case studies within the fields of rock mechanics and rock engineering. Serving as an international platform, it showcases high-quality papers addressing rock mechanics and the application of its principles and techniques in mining and civil engineering projects situated on or within rock masses. These projects encompass a wide range, including slopes, open-pit mines, quarries, shafts, tunnels, caverns, underground mines, metro systems, dams, hydro-electric stations, geothermal energy, petroleum engineering, and radioactive waste disposal. The journal welcomes submissions on various topics, with particular interest in theoretical advancements, analytical and numerical methods, rock testing, site investigation, and case studies.