Effect of Acid and Alkaline Environment on Dynamic Strength and Porosity Characteristics of Bursting Liability Coal

In order to investigate the inﬂuence of acid and alkaline environment on dynamic strength and porosity characteristics of bursting liability coal, scanning electron microscopy (SEM) and X-ray diﬀraction (XRD) analysis were used to compare the micro-structures of coal with diﬀerent bursting liabilities. A split Hopkinson bar (SHPB) was used to test the dynamic compressive strength and tensile strength of coal samples with diﬀerent bursting liabilities. The results show that the surface micromorphology and structure characteristics of coal samples with diﬀerent bursting liabilities are representatives, which can be used as an auxiliary basis to determine the bursting liability of coal seam. The microstructure of coal with strong bursting liability is characterized by mylonitic, fragmentary, and brecciated structure, and the microstructure is diverse and complex. However, the microstructure of no bursting liability coal is single and uniform. Coal with strong bursting liability shows tensile, compressive, and shear cracks produced by tectonic action, and the distribution of cracks is complicated. The development of ﬁssures is greatly aﬀected by the degree of coal metamorphism, organic components, minerals, and other factors. Under acidic and alkaline environments, the decrease amplitude of tensile strength of coal is obviously larger than that in neutral solution, which indicates that under the action of acid-based solution soaking, the easily soluble minerals in coal react with hydrogen ions and hydroxyl ions in solution obviously. Porosity increment in acidic environment is much larger than that in alkaline and neutral environments. The strong bursting liability coal is more sensitive to acidic environment, while the no bursting liability coal is more sensitive to alkaline environment.


Introduction
With the development of the technology of hydraulic fracturing and carbon dioxide gas fracturing to extract coalbed methane, the property transformation of coal reservoir and the scope of mining are expanding [1,2]. How to use a reasonable fracturing fluid to make the coal reservoir achieve the best fracturing permeability effect has become one of the important issues in the current research of efficient CBM extraction engineering [3,4]. In addition, the stability of carbon dioxide storage in the deep nonrecoverable coal seam determines the effectiveness of the underground storage technology of carbon dioxide. Previous studies have shown that water in nature is rarely completely neutral, generally (weakly) acidic, or (weakly) alkaline hydrochemical solution [5]. After the rock mass is eroded by the water chemical solution because the water solution takes away part of the cement, the connection between the mineral aggregates is weakened. ere are many microcracks and holes in the rock mass, and the porosity increases, which leads to the deterioration of the strength and other macroproperties of the rock mass. is is a threat to the long-term stability of rock engineering.
In mining engineering, due to long-term precipitation and groundwater supplement, the water stored in the underground reservoir of coal mine may cause the change of acid-base property of water, which will weaken the stability of coal pillar dam structure. Under the action of earthquake or blasting and other dynamic load disturbances, the instability of coal pillar dam structure may be caused [6]. At present, the physical and mechanical properties of coal have been widely studied, such as compressive strength [7,8], tensile strength [9][10][11], fracture characteristics [12,13], elastic modulus [14], shear strength [15], and triaxial strength [16]. However, the change of strength characteristics and porosity of coal under the influence of acid-base environment has not been reported. However, this topic not only has an important impact on the efficient extraction of coal seam gas fracturing and underground storage of carbon dioxide but also has an important impact on the stability of the underground reservoir coal pillar dam. erefore, it is necessary to study the influence of acid-base environment on the strength and porosity of coal.
ere are two main branches in the study of water rock interaction: one focuses on the influence of water on rock chemistry and the other focuses on the influence of water on rock physical mechanics. In a broad sense, water rock interaction can be divided into three categories: (1) water rock chemical interaction, including dissolution, hydration, acid-base erosion, chemical precipitation, oxidationreduction, and ion exchange [17]; (2) water rock physical interaction, including lubrication, argillization, softening, drying wetting cycle, and freeze-thaw cycle [18]; and (3) water rock mechanical interaction, mainly including hydrostatic pressure and hydrodynamic pressure [19]. In recent decades, many scholars have performed a lot of meaningful research works on water-rock chemical interaction, mainly focusing on the effect of chemical solution on the macroscopic mechanical properties of rocks. e corrosion mechanism of different chemicals on rocks was compared by Rebinder [20]. Combined with Griffith strength theory, the mechanism of the reduction of mineral surface energy and crack growth caused by the adsorption of chemical substances was discussed. Feucht and Logan [21] carried out triaxial tests on sandstone specimens with prefabricated cracks after soaking in saturated water, sodium chloride solution, calcium chloride solution, and sodium sulfate solution. e influence of hydrochemical solution on the strength of sandstone is analyzed, and the influence of different water solutions on the friction strength and friction factor of precracked sandstone is discussed. Feng et al. [22,23] studied the fracture characteristics of granite under different aqueous solution environments through the immersion test and fracture test. e time fractal characteristics in the process of stress increase, creep, and relaxation are analyzed. Based on the above analysis, the research on the interaction between water and rock is mainly focused on the simple fitting of macro and microobservation data, and the degradation law of the mechanical parameters of rock samples with the number of dry and wet cycles is obtained. However, there are few literatures on the mechanism of coal deterioration caused by drying and wetting, especially on the impact of acidbase environment on bursting liability coal.
In view of the complexity of the degradation mechanism of coal under the action of dry-wet cycle in acid-base environment, the degradation laws of strength parameters and porosity characteristics of coal under the action of acid-base environment (pH � 4, 7, 9) and dry-wet cycle (n � 1, 3, 6, 10) were studied on the basis of the microtest, dynamic compression, and tensile test of coal. Chemical kinetics and porosity evolution law are used to explain the degradation mechanism of coal with different bursting liabilities.

Specimen Preparation.
e coal samples with different bursting liabilities were taken from different coal seams of Qinneng No. 3 Mine, Qinhuangdao City, Hebei Province, China. To study the dynamic compressive and tensile strength of coal samples, cylindrical samples and Brazilian disc samples were made, respectively. In order to simulate the actual situation of natural water solution, referring to Zhang et al. [24], the lower limit of the pH value under acidic condition is 4, and the upper limit of the pH value under alkaline condition is 9.
ere are three kinds of water retention solutions used: distilled water with pH � 7, acid solution with pH � 4, and alkaline solution with pH � 9. First, the mineral composition of coal samples was tested, and then, the samples were soaked in different pH values (pH � 4, 7, 9) for 1, 3, 6, and 10 times of dry-wet cycles. After the cycles, the saturated samples and the dry samples dried for 24 h were subjected to dynamic compression and tensile tests. Finally, the variation of porosity was analyzed.
ere are 78 coal samples used for the dynamic uniaxial compression test, which are divided into 13 groups (0-12 groups) with 6 specimens in each group, 3 in each of two categories: strong bursting liability and no bursting liability. Group 0 specimens are the original specimens without wetdry cycling. Groups 1, 2, 3, and 4 specimens are subjected to uniaxial compression tests after 1, 3, 6, and 10 wet-dry cycles with soaking solution pH � 7. e 5th, 6th, 7th, and 8th groups of specimens were subjected to uniaxial tests after 1, 3, 6, and 10 wet-dry cycles with immersed solution pH � 4. e 9th, 10th, 11th, and 12th groups of specimens were subjected to uniaxial compression tests after 1, 3, 6, and 10 wet and dry cycles with immersed solution of pH � 9, respectively. e saturated water absorption of coal sample is determined by the vacuum pumping method, and the test results are shown in Figure 1. It can be found that the water absorption of coal with strong bursting liability is lower than that of coal with no bursting liability. e water absorption of coal sample is the highest in acid environment with pH � 4, followed by alkalinity, and the lowest in neutral environment. e results show that the dissolution effect of acid is the strongest and that of alkaline is greater than that of neutral solution.

2
Shock and Vibration

Experimental System.
e loading device for the dynamic mechanical test of coal is a split Hopkinson pressure bar (SHPB) loading system. e SHPB dynamic rock mechanics test system is shown in Figure 2. e Hopkinson rod is made of 35CrMn steel with a density of 7800 kg/m 3 , elastic modulus of 200 GPa, and Poisson's ratio of 0.28. e length and diameter of input and output rods of SHPB loading system are 2 m and 0.05 m, respectively. A strain gauge is attached to the middle of the input rod and the output rod to record the deformation of the rod. e launching pressure of SHPB loading device is set to 0.50 MPa. Figure 3 is the dynamic balance verification of typical coal sample. It can be seen that the force balance is satisfied in the loading process of sample, and the static theory can be used for analysis.

Microstructure Characteristics of Bursting Liability Coal.
Due to the complexity of coal itself and the limitation of research methods, the previous research on the microstructure and macerals of impact prone coal is lack of systematicness. However, in recent years, with the development of X-ray diffraction (XRD) in the basic research of coal composition and structure in coal chemistry, scanning electron microscopy (SEM), and optical electron microscopy observation technology developed in 1980s, it is possible to analyze the microstructure, minerals, and macerals of coal with bursting liability. erefore, the relationship between the microstructure characteristics and the bursting liability of coal can be systematically analyzed. Figure 4 shows the XRD analysis results of coal samples with different bursting liabilities. It is found that the higher the bursting liability of coal seam, the lower the content of clay minerals; however, the higher the content of amorphous and quartz. Based on the X-ray diffraction spectra, the values of the microcrystalline parameters of the tested coal samples can be calculated according to the relevant equations of coal petrology and coal chemistry, and then, their influence on the bursting liability of coal can be analyzed. e average stacking thickness L c of the microcrystalline lamellae of the coal sample was chosen as the microcrystalline parameter of the coal, which was calculated as follows: where λ is the wavelength of X-rays, θ 002 is the peak position of peak (002), and β 002 is the full width of half maximum intensity. e comparative results of XRD microcrystalline parameters of coal samples (Table 1) show that the smaller the average stacking thickness of microcrystalline lamellae, i.e., the smaller the L c , the greater the bursting liability of the coal.
Previous studies on the surface micromorphology of coal have mainly focused on coal with gas outburst category, while SEM studies on the microstructure of bursting liability coal are very few. erefore, on the basis of the previous study on the microstructure characteristics of coal and gas outburst coal, the surface microstructure of coal with different bursting liabilities was observed by using a scanning electron microscope (SEM) to analyze the surface microstructure characteristics of coal with different bursting liabilities. It is very necessary and beneficial to deeply understand the micromechanism of coal rock dynamic instability and accurately identify the coal seam bursting liability. Figure 5 shows the surface micromorphology of coal samples with different bursting liabilities. e strong bursting liability coal shows scaly and mylonitic microstructure, as shown in Figures 5(a) and 5(b). Mylonitic structure is usually produced after the coal sample loses   confining pressure, which is also a common microstructure in mylonitic coal. Once the confining pressure of this kind of coal is lost, some of the coal mass will show powder-like, scale-like microstructure. e more the mylonitic structure content in coal, the greater the damage degree of coal mass and the lower the permeability of coal seam. It also shows that under the same geological and stress field conditions, strong bursting liability coal is most prone to sudden failure of coal mass. However, the weak bursting liability coal shows a sheet-like and intergranular porous structure, as shown in According to the analysis of surface micromorphology characteristics of coal with different bursting liabilities, the surface micromorphology and structure characteristics of coal samples with different bursting liabilities are representative, which can be used as an auxiliary basis to determine the bursting liability of coal seam. In addition, the microstructure of coal with strong bursting liability is characterized by mylonitic, fragmentary, and brecciated structure, and the microstructure is diverse and complex. However, the microstructure of no bursting liability coal is single and uniform. e scanning electron microscope (SEM) observation surface is a two-dimensional natural section, which can be used to observe and study the development characteristics of fractures from multiple angles, including fracture properties, size, development background, filling, opening degree, density, and the relationship between fractures and bedding, components, and so on. e SEM observation scale ranges from nanometer to micrometer, including cracks in and between coal matrix blocks. Figure 6 shows the distribution characteristics of fractures on parallel bedding plane of coal samples with different bursting liabilities. It can be found that the fissures in coal with strong bursting liability (Figures 6(a) and 6(b)) show the characteristics of exogenous fissures, which are obviously influenced by geological tectonic stress and mainly consist of compressive, tensile, and shear fissures. Tensile fracture is the result of brittle deformation of coal. In statistics, the directionality of tensional cracks can reflect the characteristics of the regional stress field. Cracks in coal with weak bursting liability appear as 10 μm-30 μm microfissure. e connectivity between the cracks is obvious. e morphological characteristics and distribution of microfissures in coal are related to the bursting liability of coal. Coal with strong bursting liability shows tensile, compressive, and shear cracks produced by tectonic action, and the distribution of cracks is complicated. e development of fissures is greatly affected by the degree of coal metamorphism, organic components, minerals, and other factors.

Acid and Alkaline Environment on Dynamic Strength of Bursting Liability
Coal. In order to analyze the influence of acid-base environment on the dynamic strength of coal, the dynamic compression and tensile tests of coal with different bursting liabilities were carried out to test the influence of different pH values on the strength. e uniaxial stressstrain curves of coal under different acid-base environments and different cycles were obtained by the dynamic uniaxial compression test, as shown in Figure 7. e total degradation degree calculation formula is defined as where σ c0 is the uniaxial compressive strength of coal without soaking solution, and σ cj is the uniaxial compressive strength of the coal soaked for j cycle stage.
Phase average deterioration is defined as where D j is the total deterioration degree of coal after the j cycle stage, and n j is the number of cycles. According to the test curves in Figure 8, the dynamic uniaxial compressive strength and deterioration degree of coal under different acid-base environments (pH � 7, 9, 4) and different cycles (n � 1, 3, 6, 10) are given in Table 2.
It can be seen from Table 2 that the total deterioration degree D j increases gradually, which indicates that the damage of coal caused by dry-wet cycle is gradual. In the early stage of dry-wet cycle, the coal is significantly affected, and the average deterioration degree is large. After that, the influence of cyclic action is reduced, and the average degradation degree is small. Under dry condition, the total deterioration of coal with strong bursting liability and no bursting liability in the first stage is 14.790% and 32.345% in acid environment (pH � 4), 10.512% and 18.398% in the first stage in alkaline environment, and 8.309% and 10.381% in neutral environment. It shows that the degradation in acid environment is significantly greater than that in neutral and alkaline environment. In the saturated state, the deterioration degree of coal increases obviously, which is due to the existence of water in the coal rock, resulting in the sharp decrease of coal strength.
A total of 78 Brazilian splitting test specimens were divided into 13 groups, with a total of 10 specimens in each group, including 3 specimens in two states of dry and    Shock and Vibration saturated. Group 0 was the original specimen without the dry-wetting cycle. Groups 1, 2, 3, and 4 were tested after 1, 3, 6, and 10 dry-wetting cycles in soaking solution with pH � 7, respectively. Groups 5, 6, 7, and 8 were tested after 1, 3, 6, and 10 dry-wet cycles in soaking solution with pH � 4, respectively. Groups 9, 10, 11, and 12 were tested after 1, 3, 6, and 10 dry-wet cycles in soaking solution with pH � 9, respectively.
It can be seen from Table 3 that the tensile strength of coal decreases with the increase of dry-wet cycles. e deterioration degree is faster in the early stage and slower in the late stage ( Figure 9). Under acidic and alkaline environment, the decrease amplitude of tensile strength of coal is obviously larger than that in neutral solution, which indicates that under the action of acid-base solution soaking, the easily soluble minerals in coal react with hydrogen ions and hydroxyl ions in solution obviously, resulting in pores and microcracks, leading to the rapid formation of cracks in coal and full penetration. Compared with the coal with strong bursting liability, the strength of the coal without bursting liability is lower, but the degradation degree is higher.

Acid and Alkaline Environment on Porosity Characteristics of Bursting Liability Coal.
Due to the complex structural plane and the diversity of mineral composition, the failure mechanism of rock under stress, physical, and chemical action is far from clear. After the action of hydrochemical solution, the internal microstructure of rock mass changes, which makes its physical and mechanical properties worse and threatens the long-term stability of rock engineering. Porosity has an important influence on the strength of rock. A series of complex physical and chemical interactions take place between the minerals of coal in chemical solution and the reaction particles (e.g., H + ) in solution. It will lead to coal dissolution, which change the porosity of coal. Due to the reaction-migration and other physical and chemical processes after water erosion, some active minerals in coal undergo dissolution, adsorption, and other chemical processes. e dissolution reaction causes the minerals to dissolve, and the ionic substances generated migrate out of the coal to form voids. e adsorption results in a large number of particles covering the mineral surface of coal and blocking the pore channels in the coal. e final result of this reaction-migration-adsorption is that the pore structure inside the coal changes.
If the change of porosity of coal specimen during the action of aqueous solution is mainly caused by the dissolution and migration of constituent minerals in coal, then the change of porosity of coal specimen can be expressed by the following formula: where φ is the porosity, φ 0 is the initial porosity, and i refers to various minerals.   Incremental porosity of coal in each stage can be calculated by formula (4), as shown in Figure 10. It can be concluded that the porosity of minerals decreases linearly in stages 1, 2, and 3. In stage 4, however, the increase in porosity begins to ease down due to the decrease in the dissolution rate of minerals. Porosity increment in acidic environment is much larger than that in alkaline and neutral environment. Porosity increment in alkaline environment is slightly larger than that in neutral environment, indicating that acidic environment is the most effective way to dissolve cements. Porosity increment of strongly bursting liability coal in acidic environment is initially greater than that of no bursting liability coal, while it is opposite in alkaline environment. It indicates that strong bursting liability coal is more sensitive to acidic environment, while no bursting liability coal is more sensitive to alkaline environment.

Conclusions
(a) e strong bursting liability coal shows scaly and mylonitic microstructure; however, the weak bursting liability coal shows a sheet-like and intergranular porous structure. e no bursting liability coal shows shell-like and porous microstructure. e surface micromorphology and structure characteristics of coal samples with different bursting liabilities are representative, which can be used as an auxiliary basis to determine the bursting liability of coal seam. In addition, the microstructure of coal with strong bursting liability is characterized by mylonitic, fragmentary, and brecciated structure, and the microstructure is diverse and complex. However, the microstructure of no bursting liability coal is single and uniform. (b) e morphological characteristics and distribution of microfissures in coal are related to the bursting liability of coal. Coal with strong bursting liability shows tensile, compressive, and shear cracks produced by tectonic action, and the distribution of cracks is complicated. e development of fissures is greatly affected by the degree of coal metamorphism, organic components, minerals, and other factors. (c) e degradation in acid environment is significantly greater than that in neutral and alkaline environment. In the saturated state, the deterioration degree of coal increases obviously, which is due to the existence of water in the coal rock, resulting in the sharp decrease of coal strength. Under acidic and alkaline environment, the decrease amplitude of tensile strength of coal is obviously larger than that in neutral solution, which indicates that under the action of acid-base solution soaking, the easily soluble minerals in coal react with hydrogen ions and hydroxyl ions in solution obviously. (d) Porosity increment in acidic environment is much larger than that in alkaline and neutral environment. Porosity increment in alkaline environment is slightly larger than that in neutral environment, indicating that acidic environment is the most effective way to dissolve cements. Porosity increment of strongly bursting liability coal in acidic environment is initially greater than that of no bursting liability coal, while it is opposite in alkaline environment. It indicates that strong bursting liability coal is more sensitive to acidic environment, while no bursting liability coal is more sensitive to alkaline environment.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e authors declare that there are no conflicts of interest.