Analysis of Gas Content and Permeability Change Pattern of a Coal Reservoir in the Tectonic Positions Based on a THM Coupled Model

The theory of coalbed methane distribution controlled by tectonism is a hot issue in the field of geofluid-geotectonic interaction research. Taking the geological structure in the scale range of the 1302 working face of a Guojiahe wellfield in a Yonglong mining area as the background, this paper focuses on the basic research problem of the influence of geological structure on the control of coal reservoir gas content and uses a THM coupling model to analyze the change of coalbed gas content and distribution characteristics of different tectonic positions. The change of CBM content and permeability in the anticline, syncline, and faults is analyzed. Accordingly, the variation distance of gas content and reservoir permeability controlled by tectonism of different geological structures is quantified to provide guidance for the selection of CBM-favorable areas. The research results show that the gentle dip syncline hinge zone is a potential gas-rich area with heat preservation and low permeability, while the gentle dip anticline hinge zone is a gas-poor area with low temperature and low pressure and high permeability. The thick coal seam zone of the syncline hinge zone is the potential gas accumulation zone, and the high-permeability area is near the fault plane of a normal fault. The coal matrix near the normal fault is subjected to tensile tectonic stresses to form tensional fissures, and the coal seam in the fault plane area is susceptible to coalbed gas dispersion and increases the permeability of the coal reservoir. The variation distance of gas content and reservoir permeability controlled by the normal fault within the Guojiahe wellfield is 37 m and 54 m from the fault plane, respectively.


Introduction
The influence of geological structures on the gas content of coal seams is a hot issue in the field of interaction between geological fluids and geological structures. Therefore, it is of great theoretical significance and engineering application to study the characteristics and changes of coalbed methane (CBM) distribution under geotectonic settings. The published research results show that the "generation, accumulation, and preservation" of CBM is not only closely related to the ground stress, coal seam buried depth, and paleogeothermal and gas generation history under the control of tectonic evolution [1][2][3][4][5][6] but also influenced by the joint effect of formation pressure, lithology of surrounding rock, and microstructural characteristics of a coal reservoir [7][8][9][10][11][12][13], which means that when the environmental conditions such as temperature, stress, and seepage of coal reservoirs change due to tectonism, the gas content and its distribution characteristics in coal seams will change. Therefore, the deposition, generation, and preservation of CBM under the tectonism are the key criteria for CBM enrichment and reservoir formation, which is an important guideline for the efficient development of CBM.
The theory of CBM distribution controlled by tectonism integrates coalfield geology, gas geology, and fluid mechanics disciplines. Many domestic and foreign research results and findings have shown a close relationship between geological structure and gas content [14][15][16]. It is generally agreed that there is a clear pattern of CBM occurrence in a folded zone [17][18][19]. The results of CBM enrichment investigations in the Yangquan mining area in the Qinshui Basin, the Fuxin mining area in northeast China, the Pingdingshan mining area, and the Hancheng mining area in China all indicate that the syncline tectonic area has significant gas-rich characteristics [16,18,[20][21][22]. With the great attention to the safe and efficient exploitation of coal seams in China in recent years, the technology of CBM exploitation and extraction has been developed; in particular, the basic theoretical research results on pore-fissure seepage and reservoir properties are fruitful [23][24][25][26][27]. In particular, numerical simulation, X-ray CT scanning, scanning, and hydraulic permeability enhancement methods have been widely used in the evaluation of reservoir properties and production enhancement technology [28][29][30][31][32][33]. However, the physical condition (temperature, permeability, reservoir structure, etc.) of a reservoir has been less considered in both CBM extraction and utilization technologies and mine gas management. In order to quantitatively study the relationship between multiphysical field changes and tectonic types in coal reservoirs, we start from considering the joint effect of temperature, stress, and seepage fields inside coal seams. In this paper, the coupled thermal-hydraulicmechanical (THM) numerical model is used to calculate the variation law of CBM content, reservoir pressure, temperature, and permeability parameters in different tectonic positions and to propose favorable conditions suitable for the efficient development of CBM in the Guojiahe wellfield, which has certain engineering research significance.

Geological Structure and Gas Control
Characteristics of the Study Area 2.1. Overview of Geological Tectonics in the Study Area. The study area is located in the northern part of the Weibei flexure belt first-grade tectonic unit in the southern part of the Ordos Basin and belongs to the Binchang depression thirdgrade tectonic unit. Under the influence of the Indonian-Yanshanian period near north-south tectonic movement, several dip folds have been developed in the Guojiahe wellfield [12]. The axial dip direction generally extends along the north-east-east or near east-west direction, with the dip angle of both limbs ranging from 3 to 10°, showing a gentle dip fold tectonic pattern. There are three large-scale folds in and around the study area, namely, the Getousi anticline in the south of the wellfield, the Liangting anticline in the west, and the Caizigou-Zhangbagou syncline in the east-central part of the wellfield (Figure 1). The Jurassic structure is generally a gentle dip fold in the NE-NEE strike direction, with little variation in occurrence, accompanied by a small number of tension faults in the near east-west direction. The coal- 2.2. Investigation of the Gas Content of Coal Seams in the Study Area. The Guojiahe wellfield has developed a synsedimentary fold, and the coal seam in the axial part of an anticline is thin, which often does not have CBM preservation conditions. A gentle dip syncline is mostly developed in the area, and the coal seam in the axial part of a syncline is thicker, which has good conditions for gas generation; the larger the dip angle of the two limbs of the syncline, the easier it is for CBM to escape; the smaller the dip angle of the two limbs, the fracture is not developed or the reverse fault is developed, which is more favorable for CBM preservation.
In the large scale of the gentle dip syncline, due to the development of normal longitudinal fault and secondary folds on both limbs, CBM is easy to escape along the faults on both limbs and the fractures at the top of the secondary anticline. Therefore, the best-preserved CBM is often located in the secondary syncline part of the syncline. In order to clarify the influence of the secondary structure on the gas content, this paper analyzes the gas content in different structural parts of the no. 33, no. 15, and no. 16 prospecting lines (as shown in (Figure 2). In prospecting line no. 33, the gas content in hole G33-5 of the axial part of the syncline is larger than that in hole G33-3 of the two limbs, larger than that in hole G33-7 of the anticline limbs with a normal fault part, and larger than that in hole G33-6 of the axial part of the anticline (Figure 2(a)). In prospecting line no. 15, the gas content of drill hole G15-3 in the deep part of both limbs of the syncline is greater than the gas content of drill hole G15-2 and drill hole X21 in the shallow part of both limbs ( Figure 2(b)). Based on the CBM preservation conditions, the anticline structure can be divided into three basic types: symmetric anticline, asymmetric anticline, and secondary anticline. In the symmetrical anticline type, the fractures at the top of large anticlines are densely developed, forming a gas transportation channel. Therefore, the axial part of the anticline's gas content tends to be poor, while the gas content becomes better in the direction of both limbs and plunging part. If the intensity of tectonic extrusion and deformation increases, leading to the development of a reverse fault system in the anticline axis, it is to a certain extent favorable to the preservation of CBM and its gas content is better. The top of the asymmetric anticline is mostly developed with tensile fractures, and the CBM is often better preserved in the slow limb because the reverse fault blocks it. The gas-bearing property of the no. 16 prospecting line in the syncline-flexureanticline with normal fault part drill hole G16-4 shown in Figure 2(c) is greater than that of the axial part of syncline X27 drill hole, which is greater than that of the gentle dip syncline limbs G16-3 drill hole and G16-5 drill hole.

Geofluids
The two limbs of the syncline or anticline develop a tensional normal fault, which destroys the coal seam's continuity. The low gas content tested in the 33-33 ′ survey borehole shown in Figure 2(a) indicates that the methane escaped in large quantities along the fault or deteriorated the overall gas-bearing properties, resulting in a great heterogeneity in the regional distribution of gas-bearing properties.

Types of Gas-Controlling Structures in the Guojiahe
Wellfield. The tectonics of the Guojiahe wellfield can be summarized as extrusion and extensional tectonics, which can be summarized into three types: gentle dip syncline, anticline and secondary anticline, and normal fault according to the combination of tectonic form and different types of tectonics. The gas content of 13 CBM boreholes in different structural parts of the three prospecting lines in the study area was analyzed (Table 1), and the influence of the structural parts on the CBM content was obtained in descending order: the deep buried part of gentle dip syncline limbs is larger than the axial part of the syncline, larger than secondary anticline limbs with a normal fault part, larger than the secondary axial part of the anticline, and larger than the slow dip shallow buried part of syncline limbs. The basic types of gas-controlling structures in the Guojiahe wellfield are divided into the shallow buried part of syncline limbs, axial part of the syncline, syncline upwarping part, intersection part of syncline and secondary syncline limbs, the syncline and secondary syncline, the axial part of the anticline and secondary anticline with a normal fault ( Table 2).

Mechanism of the Thermal-Hydraulic-Mechanical
Model. The thermal-hydraulic-mechanical coupling relationship of CBM is studied; i.e., the distribution and change law of CBM under the interaction of the temperature field, seepage field, and stress field are considered. The methane gas in the coalbed is mainly stored on the surface of the coal matrix in the adsorbed state, and the changes of reservoir pressure and temperature affect the adsorption state of methane gas and the production of CBM. The essence of its intrinsic physical effects is the influence of ground stress, reservoir temperature, and pressure on the parameters of gas content and reservoir permeability [27,34]. In this research, with the help of the COMSOL Multiphysics numerical software platform, a coupled thermal-hydraulic-mechanical model of CBM distribution controlled by tectonism is established. According to the physical parameters of coalbed and CBM measured in the study area, a coefficient partial differential equation (PDE) is established. Its simultaneous solution can describe the heat conduction equation and linear elastic deformation equation of CBM flowing in the coalbed [35][36][37].
The partial differential equations of the evolution of each physical field are listed in equations (1)- (3). The calculation should consider the flow characteristics and distribution characteristics of CBM due to the coupling effect of the thermal-hydraulic-mechanical model.  Figure 1: Geological and tectonic features of the study area.

Geofluids
Based on the above considerations, a realistic numerical thermal-hydraulic-mechanical model of CBM is proposed, based on the following assumptions: (1) the coal matrix is an elastic porous medium composed of pores and fissures, (2) the coal matrix is compressible and conforms to the small deformation assumption, (3) the gasdynamic viscosity is not affected by temperature, (4) the CBM is an ideal gas and conforms to the ideal gas equation of state, (5) the matrix pore pressure in the coal of CBM is saturated, (6) the temperature of the gas at the same point is equal to the temperature of the coal matrix, and (7) the matrix pore pressure is equal to the fracture pressure [36].
The expression of the mathematical equation for the coupled temperature field of CBM in the coal matrix is

Geofluids
where η is the thermal conductivity of the coal matrix (J/m-s-K), ∇ 2 is the Laplace operator symbol, T is the temperature variable (K), T 0 is the initial temperature of the coal seam (K), Q is the CBM seepage velocity vector (m/s), q is the CBM content per unit volume of methane-containing coal (m 3 /t), ρ is the bulk weight of coal (kg/m 3 ), C v is the specific heat capacity of coal (J/kg-K), and θ T is the thermal stress coefficient. Langmuir volume constant a and Langmuir pressure constant b are set as temperature-dependent functions aðTÞ and bðTÞ, and θ pr is the stress coefficient due to CBM pressure. It is generally accepted that adsorbed and free methane in the coal matrix obeys the modified Langmuir adsorption equilibrium equation and the state's real gas equation, respectively.
where q is the CBM content per unit volume of methanecontaining coal (m 3 /t); a is the Langmuir volume constant of methane in the coal matrix; b is the Langmuir pressure constant of methane in the coal matrix; c is the coal quality correction parameter (kg/m 3 ), where c = ρg × ð100 − A − MÞ /100/ð1 + 0:31 × M), A is the ash content of the coal seam (%), and M is the coal seam moisture (%); φ is the coal seam porosity; p is the coal seam methane pressure (Pa); p n is the coal seam methane gas pressure at standard atmospheric pressure (Pa); and ρ c is the coal seam density (kg/m 3 ). The mathematical equation expression for the coupled stress field in the coal reservoir is where G is the Lame coefficient, ν is the shear modulus, u is the displacement function-independent variable, x i and x j are partial differentials of displacement, and θ ads is the adsorption stress coefficient of CBM, and the calculated solid stress field of coal rock in the model are considered based on the linear elastic model.   The mathematical equation expression of the coupled seepage field of CBM in the coal matrix considering the slip effect is where α is the coefficient of influence of CBM on the elastic modulus of the coal matrix, p n is the pressure of CBM at the standard state (MPa), c is the elastic modulus of coal matrix material without CBM (Pa), ∇p is the CBM pressure gradient within the coal seam (Pa/m), I is the source-sink term, permeability k and porosity φ are composed of functions through strain ε, temperature T (K), and CBM pressure p (Pa) with a total of three independent variables, and other coupling terms are synonymous.

Original Construction Model and Numerical Model.
According to the survey results of the geological structure of the no. 3 coal seam in the Guojiahe wellfield, the geological structure within the scale of the 1302 coal mining working face is selected as the research object (see Figure 3), and the numerical model of the geological structure is established as shown in Figure 4. It is determined that the coal seam's rightmost opening in the calculation model is the stopping line position, and the whole model develops the X3 syncline, B1 anticline, F10 normal fault, and F11 normal fault from the cutting hole to the stopping line direction, respectively, involving a total of three geological formations: anticline, normal fault, and syncline ( Table 3). The surface elevation of the 1302 coal mining working face is +1232~1440 m, the working face elevation is +730~810 m, the length is 1285 m on average on strike direction, the length is 270 m on dip direction, and the working face temperature is 293 K. In consideration of the above working face geological conditions and mining conditions, the numerical model was designed with a length of 1285 m, a height of 110 m, and corresponding stratigraphic elevations of +700 m to +810 m. The geological section of the working face was divided into planes according to the tectonic features and then imported into the COMSOL software platform for 3D model construction and triangular meshing (see Figure 4).

Basic Model Parameters.
The model calculation boundary conditions are mainly based on the actual measured temperature of the working face combined with the research results on temperature boundary conditions in related studies [35,[38][39][40]. The initial temperature of the working face (T 1 ) is 293 K, the initial temperature of the fault hanging wall (T 2 ) is 293 K, the initial temperature of the fault footwall (T 3 ) is 293 K, the initial boundary temperature of the coal seam (T 4 ) is 294 K, and the initial boundary temperature of the coal seam roof position (T roof ) is 293 K. The initial boundary temperature of the coal seam floor boundary (T floor ) is 293 K. Based on the measured coal seam gas pressure of 1.70 MPa in the extraction borehole at the working face, the overlying rock layer load f of the 1302 working face is 11.4 MPa calculated according to the vertical principal stress equation. According to Guojiahe mine rock and gas basic parameter report, physical parameters such as density, elastic modulus, Poisson's ratio of coal, and those of CBM (density, gas pressure in a standard state, and molar volume) were determined, as listed in Table 4. A triangular mesh dissects the model with a calculation error of 0.0001, and the time is set to 150 d.

Simulation Analysis of CBM Distribution Controlled by
Tectonism. As shown in Figure 5, the multiphysical field characteristics of the geological structure within the scale of the 1302 working face are calculated according to the   Geofluids thermal-hydraulic-mechanical coupling model, and it can be learned that (1) the overall CBM content q is greater than 1 m 3 /t and the CBM content in the syncline hinge zone is higher while the CBM content near the fault plane of the normal fault is low. With the advancement of mining, the CBM content at the fault plane decreases and causes the gas content near it to decrease gradually, and the influence range gradually increases, and the change tends to be stable after 100 d (Figure 5(a)). (2) The overall coal reservoir pressure shows the distribution characteristics to be high in the syncline hinge zone and low near the fault plane. With the advancement of mining, the pressure difference between the syncline hinge zone, fault plane, and surrounding coal reservoir is more significant, and the influence range of coal reservoir pressure change near the fault plane gradually increases ( Figure 5(b)). (3) The temperature difference of the coal reservoir is larger in different structural parts. The syncline hinge zone is the high-temperature zone of the coal reservoir, the temperature of the syncline limb gradually decreases, the temperature near the fault plane is lower, and the range of low-temperature zone near the fault plane gradually increases as the mining advances ( Figure 5(c)). (4) The overall coal reservoir permeability is low, about 1:88 × 10 −5 μm 2 , the syncline hinge zone reservoir permeability is small, and the permeability near the fault plane is large. With the advance of mining, the coal reservoir permeability near the fault is higher and tends to increase with the change of time ( Figure 5(d)).
In order to further study the control effect of folds and faults on the CBM content, the X3 gentle dip syncline, B1 anticline, F10 normal fault, and F11 normal fault were selected in the numerical calculation model of the 1302 coal  7 Geofluids mining face to monitor the evolution law of the temperature field, seepage field, and stress field by using a twodimensional cut-off line. The length of the monitoring line near the structure is 180 m (direction: limb→hinge zone→limb or hanging wall→fault plane→footwall) according to the development and characteristics of the structure. Since the coal seam deposits at the B1 anticline is thin, the F10 normal fault is generated near the hinge zone of the anticline under tensile stress, so monitoring lines are arranged every 60 m from the B1 anticline limb to the hinge zone, F10 fault plane, and fault plane to the anticline limb, respectively ( Figure 6).
Figures 7- Figure 8 show the characteristics of the changes of CBM content, coal reservoir pressure, temperature, and permeability from the 1st d to the 150th d of different structure types. The CBM content and coal reservoir pressure in the syncline area gradually increase as the working face advances, and the values stabilize after about 100 d,    Geofluids and the hinge zone shows obvious advantage of pressureholding reservoir formation (Figures 7(a), 8(a), and 9(a)). The coal reservoir temperature in the syncline hinge zone is higher and the permeability is lower, and the range of the high-temperature zone and low-permeability zone in the hinge zone gradually decreases with time change, and the change range tends to be stable around 100 d. Near the tectonic combination of the B1 anticline and F10 normal fault, the characteristics of coal reservoir pressure and coalbed gas content changes are consistent and synchronous, and the pressure and gas content of the anticline hinge zone are lower (Figure 8). The coal reservoir pressure is low due to  10 Geofluids the development of fractures near the two fault planes of the F10 normal fault, and the coal reservoir permeability increases while the coalbed gas is dispersed. With the change of time, the range of change of coalbed methane content, coal reservoir pressure, temperature, and permeability near the fault plane gradually expands and stabilizes after about 100 d (Figure 9). Near the F11 normal fault, the CBM content, coal reservoir pressure, temperature, and permeability change in value and influence range with the advance of the working face and stabilize after about 100 d. Near the fault plane, the coal seam gas content and coal reservoir pressure are lower under tensile stress, while the coal matrix is more continuous near the upper and footwall of the fault, which gradually has the advantage of gas richness into the reservoir with time. The coal reservoir temperature varies relatively large in different parts, and the change trend is consistent with the coal reservoir pressure as a whole. Due to the development of fault plane fractures, the permeability of the coal reservoir is significantly increased, and the range of the high-permeability zone near the fault plane gradually expands with the change of time and stabilizes after 100 d.
In order to further analyze the change process of CBM content near the syncline, anticline, and fault in different tectonic parts, the data statistics of interpolation value selected According to the change of gas content of the no. 3 coal reservoir in working face 1302 shown in Figure 10, it can be seen that the change of CBM content in different structural parts is different and the CBM content in the limb of the X3 gentle dip syncline is lower, but the hinge zone has the advantage of holding pressure and the CBM content is higher (Figure 10(a)). In the process of changing from limb-hinge zone-limb part, the CBM content shows a wide and slow arc-shaped trend of increasing and then decreasing, and the change of CBM content near the B1 anticline and F10 normal fault is relatively complicated. The CBM content in the direction of the hinge zone from the limb of the anticline gradually decreases, and the CBM content gradually decreases and falls below 0.5 m 3 /t at each of the two fault planes of the F10 normal fault and then gradually increases along the hinge zone of the anticline to form a near funnel-shaped curve with the east limb of the anticline (Figure 10(b)). Along the monitoring line of the F11 fault, from hanging wall-fault, the CBM content of the F11 fault is funnel-shaped along the monitoring line from hanging wall-fault plate-footwall and decreases significantly at the normal fault plane (Figure 10(c)).   12 Geofluids Comprehensive analysis of the data in Figures 7-10 shows that the gas content, reservoir pressure, temperature, and permeability vary nonlinearly in different tectonic sites. In the anticline hinge zone, the coal seam is thin and prone to fracture under tension force, and the internal fractures of the coal matrix is more developed, resulting in lower pressure and temperature of the coal reservoir, lower gas content, and higher permeability of the corresponding coal reservoir. The changes of coal seam gas content, reservoir pressure, and temperature in the thick coal seam part of the syncline hinge zone show the advantages of reservoir formation of pressure maintenance, heat preservation, and gas enrichment. Therefore, the gas-rich advantage of the syncline hinge zone and the gas-poor characteristic of the anticline hinge zone are mainly characterized by the wide and slow arc-shaped change of coalbed gas content. The CBM content near the normal fault shows a funnel-shaped trend, with the fault plane being the lowest point and the hanging wall and footwall decreasing toward the fault plane, respectively. In summary, the gentle dip syncline hinge zone is rich in gas with heat preservation and low permeability, while the gentle dip anticline hinge zone is poor in gas with low temperature and low pressure and high permeability, and the small normal fault within the layer shows the funnel-type gas control characteristics. The syncline hinge zone is a gas accumulation zone, and the fault plane of the normal fault is a highpermeability area of the reservoir.

Variation Distance of Gas Content and Reservoir
Permeability Controlled by Tectonism. Statistical analysis of the changes in gas content and permeability of coal reservoirs near different tectonic sites is shown in Figure 11. The coal seam gas content and coal reservoir permeability changes are complicated near the normal fault because the coal seam forms fissures under the condition of the tensional tectonic stress field. The normal fault developed within the coal seam has a small drop and does not extend to the top and bottom plates. The coal seam at the fault plane is misfractured or generates a fracture plane causing CBM dissipation while increasing the permeability of the coal reservoir.
In Figure 11(a), the CBM content of B1 anticline and F10 normal fault parts reached the minimal value at two fault planes with coordinates of (82.67, 0.29) and (94.46, 0.05), respectively, and the CBM content tends to be stable in A (46.65, 3.07) and B (137.05, 3.07) toward the anticline limbs, respectively. The fault plane is 36.02 m and 42.59 m from points A and B, respectively, and the gas content decreases by 90.5% and 98.4%, respectively, indicating that the tectonic combination of the B1 anticline and F10 normal fault, whose gas control range is 36.02 m~42.59 m from the fault plane. The CBM content of the F11 normal fault reaches a very small value at the fault plane (94.50, 0.41), which is 86.6% lower than the stable point of CBM content A and B, and the distance is 36.69 m and 37.23 m, respectively, indicating that the gas control range of the F11 normal fault is 37 m (Figure 11(b)). The above analysis shows that the CBM content in different parts of the small normal fault developed in the layer shows a funnel-shaped trend of first decreasing and then increasing, the CBM content reaches a minimal value at the fault plane, and the CBM content significantly decreases within 37 m of the two disks of the fault plane, with a decrease of 86%. The CBM content gradually tends to level off after moving away from the influence range of the fault plane.
The continuity of the coal matrix near the fault plane of the normal fault is destroyed, and the coalbed gas content is reduced while a large number of fractures are developed, which makes the permeability of the coal reservoir increase. According to Figure 11(c), the permeability near the F10 normal fault is affected by the B1 anticline tectonics, and the overall trend of slow decline-sharp increase-small fluctuation-sharp decline-slow increase is shown. At the two fault plane locations, the permeability reaches a great value of 1:988 × 10 −5 μm 2 with an increase of 2.8% and 2.5%, respectively, and the distance minima are 49.23 m and 57.23 m, respectively. The permeability of the F11 normal fault shows a trend of slowly decreasing-sharply increasing-sharply decreasing-slowly increasing in different structural parts. At the fault plane, the permeability reaches a great value of 1:988 × 10 −5 μm 2 , and the permeability increases by 2.6%, and the distance minima are 54.6 m and 54.17 m, respectively ( Figure 11(d)). From the above analysis, the permeability of the small normal fault developed in the layer is characterized by single-peak variation, the highest increase in permeability near the fault plane is about 2.6%, and the influence range is about 54 m for both walls of the fault plane.

Conclusion
In this study, the actual geological structure of the Guojiahe wellfield in the Yonglong mining area was used as the background, and the THM coupling model was used to analyze the variation law of CBM content and permeability in anticline, syncline, and normal fault tectonic sites and to reveal the variation distance of gas content and reservoir permeability controlled by tectonism in different tectonic positions. The main findings are as follows.
(1) The CBM content changes in different tectonic parts are different. The CBM content in the X3 gentle dip syncline limb is low, but the hinge zone has the advantage of pressure maintenance, and the CBM content is high. In the process of changing from the limb-hinge zone to the limb, the CBM content shows a wide and slow arc-shaped trend of increasing and then decreasing, and the CBM content changes near the B1 anticline and F10 normal fault are relatively complicated (2) The methane content of the anticline limb gradually decreases toward the hinge zone and drops below 0.5 m 3 /t at each of the two fault planes of the F10 normal fault, and then, the methane content gradually increases along the anticline hinge zone to form a near funnel-shaped curve with the east limb of the anticline. The CBM content of the F11 fault gradually increases along the anticline hinge zone and forms a 13 Geofluids near funnel-shaped curve with the east limb of the anticline; along the monitoring line from hanging wall-fault plane-footwall, the overall CBM content shows a funnel-shaped trend and decreases significantly at the normal fault plane (3) The hinge zone of the gentle dip syncline is gas-rich with low permeability, pressure maintenance, and thermal insulation, while the hinge zone of the gentle dip anticline is gas-poor with low temperature, low pressure, and high permeability. The gas accumulation zone is in the thick coal seam zone of the syncline, and the fault plane of the normal fault is near the high-permeability area of CBM. Within the Guojiahe wellfield, the variation distance of gas content and reservoir permeability controlled by tectonism is 37 m and 54 m from the fault plane, respectively

Data Availability
The experiment data used to support the findings of this study are included within the article.

Conflicts of Interest
The authors declare that they have no conflicts of interest.