Numerical Simulations of Fracture Propagation in Jointed Shale Reservoirs under CO<sub>2</sub> Fracturing

Zhang, Qi; Ma, Dawei; Liu, Jiangfeng; Wang, Jiehao; Li, Xibing; Zhou, Zilong

doi:10.1155/2019/2624716

Cited by 11 publications

(4 citation statements)

References 42 publications

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“…The damage variable is determined by comparing principal strain to maximum tensile or compressive strain based on failure criteria. The Young's modulus and permeability in the transition zone from rock to fracture is described as a function of the damage variable (Liu, Zhu, et al., 2018; J. Wang et al., 2017; J. G. Wang & Zhang, 2018; Q. Zhang et al., 2019). However, the failure criteria are based on the stress response.…”

Section: Introductionmentioning

confidence: 99%

Phase‐Field Simulation of Hydraulic Fracturing by CO₂, Water and Nitrogen in 2D and Comparison With Laboratory Data

2021

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Hydraulic fracturing by pressurized water is widely used in stimulation of wells in bedrock formations. The method requires an enormous amount of water and introduces many potential environmental issues in relation to fresh water consumption and potential contamination of drinking water supplies (Thomas et al., 2019). CO 2 is considered a more environmentally friendly alternative because it adsorbs to the rock surface, has no flowback, and does not block pores (Middleton et al., 2015). Moreover, water-based fluids tend to be trapped in formations, inhibiting oil-and gas-phase flow due to clay-mineral swelling which reduces permeability. CO 2 fracturing is a promising alternative as it results in a lower breakdown pressure and creates more extensive fractures, which increases gas and oil production rate. In recent years, hydraulic fracturing by water and by CO 2 has been extensively studied in the laboratory. In the field scale, one comprehensive trial by CO 2 for fracturing and viscosified CO 2 for proppant placement has been conducted in an

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Section: Introductionmentioning

confidence: 99%

Phase‐Field Simulation of Hydraulic Fracturing by CO₂, Water and Nitrogen in 2D and Comparison With Laboratory Data

2021

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“…There are two groups of methods that use carbon dioxide in the hydraulic fracturing process (Labuda 2014). The first of them, currently often used in shale gas extraction in the USA, is based on the utilization of so-called energized fluidsingredients preventing by receding of the space between clay particles in shale and with water and a small or large addition of carbon dioxide in the liquid state (Wang et al 2020;Li et al 2015;Zhang et al 2019). The second, patented in 2013 (Middleton et al 2014;Watts and Watts 2015), assumes the use of carbon dioxide itself, using the fact that, as it moves from liquid to gaseous CO2, it increases its volume and protects spaces in the shale rock before reducing them.…”

Section: Oil and Gas Depositsmentioning

confidence: 99%

Geological built and potential CCS perspectives in northern Poland

Kusek¹

2021

Environ. Earth Ecol.

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The world has been struggling with global warming for many years. One way to reduce this phenomenon is to limit anthropogenic carbon dioxide emission to the atmosphere, which is partly responsible for contemporary climate change. This problem is international, but each country is obliged to follow general recommendations. In Poland, the idea of underground carbon sequestration (CCS) is increasingly being considered in the last decade. Northern Poland seems to be one of the perspective areas. For this reason, the following article describes the possibility of underground CO2 injection in this area. It contains the detailed description of the geological structure of Northern Poland. Types of underground structures for sequestration were also selected. The article also describes the technical conditions for the CO2 injection process. The most numerous group of boreholes suitable for CCS are those with documented oil or gas deposits. They are usually Upper Permian, and less often Middle Cambrian or Silurian hydrocarbon geological traps, where CO2 can be used in the enhanced oil and gas recovery. There are also several boreholes with saline aquifers.

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“…where σ ij is the component of the stress tensor and f i is the component of the body force. The poroelastic response, including thermal expansion effects, defines the constitutive relation for the deformable porous medium as follows [26][27][28]:…”

Section: Coupled Thmc Responsementioning

confidence: 99%

Coupled Thermo-Hydro-Mechanical-Chemical Modeling of Permeability Evolution in a CO₂-Circulated Geothermal Reservoir

Tao

Elsworth

et al. 2019

Geofluids

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The meager availability of water as a heat transfer fluid is sometimes an impediment to enhanced geothermal system (EGS) development in semi-arid regions. One potential solution is in substituting CO2 as the working fluid in EGS. However, complex thermo-hydro-mechanical-chemical (THMC) interactions may result when CO2 is injected into the geothermal reservoir. We present a novel numerical model to describe the spatial THMC interactions and to better understand the process interactions that control the evolution of permeability and the heat transfer area. The permeability and porosity evolution accommodate changes driven by thermo-hydro-mechanical compaction/dilation and mineral precipitation/dissolution. Mechanical and hydraulic effects are demonstrated to exert a small and short-term influence on permeability change, while the thermal effects are manifest in the intermediate and short-term influence. The most significant and long-term influence on permeability change is by chemical effects, where decreases in fracture permeability may be of the order of 10-5 due to calcite precipitation in fracture throats, which causes the overall permeability to reduce to 70% of the initial permeability. The initial pressure and temperature of the injected CO2 exerts an overriding influence on permeability. In particular, an increased temperature reduces the mineral precipitation in the fracture and enhances mineral dissolution within the matrix and pore but results in mechanical closure of the fractures. Optimizing injection pressure and temperature may allow the minimization of precipitation and the maximization of heat recovery.

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Numerical Simulations of Fracture Propagation in Jointed Shale Reservoirs under CO₂ Fracturing

Cited by 11 publications

References 42 publications

Phase‐Field Simulation of Hydraulic Fracturing by CO₂, Water and Nitrogen in 2D and Comparison With Laboratory Data

Phase‐Field Simulation of Hydraulic Fracturing by CO₂, Water and Nitrogen in 2D and Comparison With Laboratory Data

Geological built and potential CCS perspectives in northern Poland

Coupled Thermo-Hydro-Mechanical-Chemical Modeling of Permeability Evolution in a CO₂-Circulated Geothermal Reservoir

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Numerical Simulations of Fracture Propagation in Jointed Shale Reservoirs under CO2 Fracturing

Cited by 11 publications

References 42 publications

Phase‐Field Simulation of Hydraulic Fracturing by CO2, Water and Nitrogen in 2D and Comparison With Laboratory Data

Phase‐Field Simulation of Hydraulic Fracturing by CO2, Water and Nitrogen in 2D and Comparison With Laboratory Data

Geological built and potential CCS perspectives in northern Poland

Coupled Thermo-Hydro-Mechanical-Chemical Modeling of Permeability Evolution in a CO2-Circulated Geothermal Reservoir

Contact Info

Product

Resources

About

Numerical Simulations of Fracture Propagation in Jointed Shale Reservoirs under CO₂ Fracturing

Phase‐Field Simulation of Hydraulic Fracturing by CO₂, Water and Nitrogen in 2D and Comparison With Laboratory Data

Phase‐Field Simulation of Hydraulic Fracturing by CO₂, Water and Nitrogen in 2D and Comparison With Laboratory Data

Coupled Thermo-Hydro-Mechanical-Chemical Modeling of Permeability Evolution in a CO₂-Circulated Geothermal Reservoir