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Review on Thermal Stimulation in Deep Geothermal Reservoirs: Thermo-Mechanical Mechanisms and Fracture Evolution

Kaituo Li, Lin Zhu, Fei Xiong, J. J. Liu, Yi Xue, Zhengzheng Cao, YueJin Zhou, Xin Liang, Ming Ji, Guannan Liu, Faning Dang

2026Processes6 citationsDOIOpen Access PDF

Abstract

Enhanced geothermal systems (EGS) are a key technology for developing deep geothermal resources, yet they face significant challenges in constructing efficient thermal reservoirs within high-stress, high-strength, and low-permeability crystalline rock formations. Traditional hydraulic fracturing (HF) techniques encounter deep challenges in these environments, including excessively high fracturing pressures, limited fracture network patterns, and the risk of induced seismicity. This paper reviews the multi-scale thermal-mechanical mechanisms, fracture evolution patterns, and control strategies associated with thermal stimulation and permeability enhancement in the modification of deep geothermal reservoirs. Research indicates that thermally induced fracturing triggers intergranular and transgranular cracks at the microscopic scale due to mineral thermal expansion mismatches, which macroscopically manifests as nonlinear degradation of rock strength and modulus. The redistribution of the thermal elastic stress field significantly lowers the breakdown pressure, while matrix thermal contraction increases fracture aperture, leading to an exponential enhancement of permeability following a cubic law. However, the high confining pressure constraints, true triaxial stress anisotropy, and thermal short-circuiting risks present substantial suppression and challenges to the effectiveness of thermal stimulation in deep in situ environments. Different fracturing media, such as water, liquid nitrogen (LN2), and supercritical CO2, exhibit varying advantages in thermal stimulation efficiency due to their unique thermal-flow characteristics. Future research should focus on the thermal-mechanical coupling mechanisms under true triaxial stress conditions, and develop intelligent control strategies for permeability enhancement and thermal short-circuiting risk mitigation. This study synthesizes existing analyses and proposes potential engineering strategies for stimulating deep EGS reservoirs, offering significant strategic value for the development of geothermal energy as a baseload renewable resource.

Topics & Concepts

Geothermal gradientHydraulic fracturingGeologyThermal expansionPetroleum engineeringGeotechnical engineeringPermeability (electromagnetism)ThermalFracture (geology)Supercritical fluidComplex fractureGeothermal energyThermal shockIntergranular corrosionMaterials scienceStress fieldStress (linguistics)Cabin pressurizationThermal energyVolcanoSteam injectionHydraulic Fracturing and Reservoir AnalysisGeothermal Energy Systems and ApplicationsCO2 Sequestration and Geologic Interactions