Acoustic Emission Characteristics and Energy Evolution of Red Sandstone Samples under Cyclic Loading and Unloading

To explore the characteristics of rock deformation and failure under cyclic loading and unloading, the MTS815 rock mechanics test system and acoustic emission (AE) signal acquisition system were used to perform cyclic loading and unloading tests on red sandstone samples. The results showed that, compared with the uniaxial compression test, cyclic loading and unloading had a certain strengthening eﬀect on the strength of the samples. The plastic deformation of the rock samples increased as the number of cycles increased. Based on AE signals, the cracking mode classiﬁcation was analyzed on the basis of the average frequency and the rise angle of the waveforms. It was observed that the Felicity ratio gradually decreased with the increase in the stress level, which showed a cumulative damage eﬀect. From the perspective of energy, the obvious increase of AE energy rate was mainly concentrated in the early and late stages of uniaxial compression, while the signiﬁcant increase of dissipated energy rate occurred in the late stage of uniaxial compression. During the cyclic loading and unloading, most of the work done by external forces in the compaction stage and the elastic stage was converted into elastic strain energy, and dissipated energy began to gradually increase in the stage of stable fracture development. In addition, it was found that the damage evolution of the rock samples changed from slow to fast, and the dissipated energy ratio increased when failure was approaching.


Introduction
Many engineering practices have shown that the rock mass is often under an unstable state of repeated loading and unloading during engineering construction, such as excavation and reinforcement of high slopes, underground mining, and tunneling [1]. Existing studies have shown that the strength and deformation laws of rocks under cyclic loading are significantly different from those under monotonic loading [2,3]. In recent years, the acoustic emission (AE) technique has been widely used in solving rock and soil mechanics problems. It can be used to continuously monitor the development and destruction process of microcracks in rock samples in real time [4] and provide precursor information on rock instability and failure [5,6].
us, the AE technique was widely used in many fields such as materials engineering [7,8], structural engineering [9,10], mechanical equipment [11,12], aerospace [13], and civil engineering [14,15]. Kaiser [16] first discovered the phenomenon of AE in engineering materials and proposed the "Kaiser effect" in 1953. en, Goodman [17] verified the Kaiser effect of rock AE through cyclic loading and unloading experiments in 1963. ereafter, the study of AE focusing on rocks has never stopped. Rudajev et al. [18] revealed the AE characteristics of the rock failure process using a uniaxial compression test. Carpinteri et al. [19] compared the AE frequency amplitude statistics of the solid during the damage process with the defect size distributions of the disordered materials and found the key parameters that define the instability conditions of the monitored structure. Fu et al. [20] observed the Kaiser effect on Brazilian splitting and bending tests of marble and established the relationship between stress, strain, and AE. Meng et al. [21] conducted uniaxial cyclic loading and unloading compression at six different loading rates to investigate the energy accumulation, evolution, and dissipation characteristics and analyzed the stress-strain relationship and AE characteristics of the rock deformation and failure process. Liang et al. [22] found the effect of cyclic loading and unloading on the mechanical properties of the rock in the postpeak stage and proved that the deformation behavior of the rock was consistent with the AE parameters. Qin et al. [23] studied the mechanical properties and AE characteristics of sandstone under different loading paths and analyzed the macroscopic failure morphology through CT scanning and 3D image reconstruction. To explore the AE characteristics of soft rock, Zhao et al. [24] performed cyclic loading and unloading AE tests on sandstone and mudstone, respectively, and studied their deformation, failure characteristics, and the law of AE activities. Liu et al. [25] studied the AE characteristics of dry and saturated basalt columnar joints under uniaxial compression and analyzed tensile damage, the damage situation, AE parameters, and rock's damage AE precursor information. Wang et al. [26] conducted an in-depth study on the AE characteristics of granite under triaxial loading and discussed the types and development time of triaxial compression cracks. e destruction of rock under cyclic loading is a dynamic evolution process from crack development and compression to structural adjustment and instability. It is inevitable to be accompanied by the generation of AE signals. erefore, to better understand the basic characteristics of rock damage and failure process, it is necessary to use the AE technique for real-time monitoring, which can contribute to a deep understanding of the damage and failure characteristics of rock samples during cyclic loading and unloading.
Meanwhile, the deformation and destruction of rocks are driven by energy evolution activities from the energy perspective.
is perspective includes energy input, storage, dissipation, and release, which are essentially energy conversion [27,28]. It is an effective method to explore the rock failure problem under cyclic loading through the energy mechanism. Xie et al. [29,30] explained the energy dissipation mechanism in the process of rock deformation and failure from the thermodynamics perspective and proposed a damage evolution equation based on energy dissipation analysis. You and Hua [31] and Chen et al. [32] found that the absorbed energy had a linear relationship with the confining pressure during rock failure. Carpinteri et al. [33] analyzed the experimental results of compression tests on cylindrical specimens of different types of rocks and concrete from the perspective of the balance between the energy stored, released, and absorbed during the complete loading process. Zhang et al. [34] investigated the effect of the confining pressure on the energy evolution characteristics and distribution relations under triaxial cyclic loading and unloading experiments. Gong et al. [35,36] selected various rock samples for uniaxial compression, loading and unloading tests under different stress levels, and proposed a linear energy storage method and a rock burst tendency criterion.
In summary, a great number of efforts have been dedicated to the research on the mechanical properties, AE characteristics, and energy evolution laws of the loaded rock. However, the cyclic loading and unloading effects have a broad engineering background. It remains necessary to study the AE characteristics and energy evolution laws of rocks under cyclic loading and unloading, which is helpful to explore the corresponding relationship between the damage and destruction process of the loaded rock and the AE and energy. In this paper, cyclic loading and unloading tests of red sandstone samples were performed to mainly investigate the characteristics of AE and energy evolution in the entire process of rock deformation and failure.

Sample Preparation.
e red sandstone samples tested in the experiment were taken from Yueyang, Hunan Province, China. e sandstone samples are maroon with a fine grain structure and uniform texture. e main mineral components are quartz, feldspar, calcite, and iron. According to the international standards from the International Society for Rock Mechanics (ISRM), the rock samples were processed into cylindrical standard samples with a diameter of 50 mm and a height of 100 mm. e parallelism of the upper and lower surfaces was controlled within 0.05 mm, and the surface flatness was less than 0.02 mm. e processed samples before the test were strictly screened to eliminate the samples with obvious damages and cracks on the surface. Moreover, the samples with abnormal wave speed and density were also eliminated through the ultrasonic test and density test. e red sandstone samples in the test were grouped and numbered, as listed in Table 1.

Experimental System.
e MTS815.04 rock mechanics test system manufactured by the American MTS company was utilized in the test as the main loading equipment. e test system is composed of a loading system, a control system, and a monitoring system. It is a multifunctional electrohydraulic servo-controlled rigidity testing machine with excellent manual and program control functions, especially used for rock and concrete experiments. It has three independent closed-loop servo control functions for axial pressure, confining pressure, and pore water pressure. e 12CHsPCI-2 AE test and analysis system produced by the Physical Acoustic Corporation was simultaneously applied to track the AE characteristics of samples during the loading process, as shown in Figure 1. A pair of axial and lateral extensometers was used for the deformation measurement, and six AE sensors were closely adhered to the rock sample to record AE signals, as shown in Figure 2.
Combining previous research and experiments, it is found that the sources of electromagnetic noises in the signal include flexing, twisting or transient impacting on coaxial cables, the poor contact of the AE probe, and the influence of the electromagnetic field generated by the external environment. And it was also proved that most of the noise interference can be effectively filtered out by setting a threshold of 40 dB. erefore, 40 dB was set as the threshold in this experiment to avoid false signals generation.

Test Procedures.
Uniaxial compression tests on samples R-1, R-2, and R-3 were first conducted to obtain an approximate uniaxial compressive strength, which can provide a reference for the formulation of the cyclic loading and unloading test program. Next, the cyclic loading and unloading test adopted axial stress control mode with a loading rate of 0.25 MPa/s. e loading increment for each stage was set as 10 MPa. Each stage was first loaded to the preset value and then unloaded to 0 MPa. e above loading and unloading process was repeated until the red sandstone samples were fractured. e stress loading path was shown in Figure 3. Figure 4 showed the stress-strain curves of rock samples in uniaxial compression tests. e complete stress-strain curves of rock samples under uniaxial cyclic loading and unloading were shown in Figure 5.

Strength and Deformation Characteristics Analysis.
e average compressive strength of the rock samples under uniaxial compression was 74 MPa, while the average compressive strength of the rock samples under uniaxial cyclic loading and unloading was 78 MPa with an increase of 5.4% compared to uniaxial compression. e rock sample used in the test was red sandstone in the natural state, and there were inevitably original cracks inside. Compared with the sample under uniaxial compression, there was only a microcrack compaction stage, while the microcracks inside the sample under cyclic loading were repeatedly pressed and closed.
us, the compressive strength of the sample increased. Figures 4 and 5 show that the envelope line of the uniaxial cyclic loading and unloading curves was similar to that of the uniaxial loading curves, which reflected the deformation memory of rock material. Some scholars obtained similar conclusions in the study of red sandstone [37]. In addition, the path of the unloading curve was not along the loading curve during uniaxial cyclic loading and unloading but lower than the loading curve. e loading curve and unloading curve did not coincide, forming a hysteresis loop, which was similar to a willow leaf with a wide middle part and sharp ends. When it was unloaded to 0 MPa, certain irreversible plastic deformation was generated. e elastic deformation recovered after each unloading, and the hysteresis loop continuously migrated forward. e area of the hysteresis loop was also gradually increased, indicating that the plastic deformation of the sample under cyclic loading and unloading would increase with the increase of the number of cycles.

AE Characteristics of Rock Samples under Uniaxial
Compression.
e AE generated by the loaded rock was mainly related to the generation, expansion, and connection of cracks, which can be used to reflect the internal damage of the rock. Figures 6 and 7 showed the curves of AE energy, AE count, and axial stress with respect to the loading time. AE energy was derived from the integral of the squared voltage  signal divided by the reference resistance (10 k-ohm) over the duration of the AE waveform packet. It can be used as a characteristic value to characterize the true energy of AE impact. AE count was obtained by counting the number of AE signal excursions exceeding the AE threshold. e above parameters were directly exported through AEwin for PCI2 software. Figures 6 and 7 showed that the stress-time curves of the rock samples can be roughly divided into four stages based on the distribution characteristics of the AE energy and count. Section AB was the pore and fissure compaction stage, during which the stress-time curve showed an upward concave shape. Only a few AE events occurred at this stage, and the AE energy was relatively low. e AE at this stage was mainly generated by the compression of the initial crack inside the rock sample. Section BC was the linear elastic stage of the rock sample, with the stress-time curve being approximately linear. Since this process was mainly elastic deformation and there was little microcrack propagation, AE count and energy remained basically calm. In section CD, the rock sample entered the plastic stage of unsteady fracture development. Point C was the yield point. e AE began to gradually increase, and new cracks were continuously generated inside the rock sample. e development of microfracture has qualitatively changed, and the rupture continued to develop until the sample was completely fractured, resulting in the fact that AE count and energy drastically increased to the highest value. Section DE was the postfailure stage. e bearing capacity of the rock sample rapidly decreased. At this time, the microfracture was coalesced to form a macroscopic fracture surface. AE count still appeared after the rock sample fractured and reached a large value, but there was no specific law. In Figures 8 and 9, the stress level in the initial cycle was relatively low. e rock samples were in the compacting stage of primary fissures. New cracks were not produced, and the number of AE signals was small. e stress level further increased with the increase of the number of cycles, and new cracks began to appear in the rock samples. e AE energy was released as a result of the development and coalescence of cracks. e AE activity gradually entered the active period and reached the maximum at the last loading and unloading failure. In addition, the AE count was basically consistent with the change in AE energy. e AE count and AE energy significantly increased from the fourth cycle. e preset stress for the fourth cycle was 40 MPa, which was approximately 54% of the uniaxial compressive strength. erefore, when the samples were loaded to 54% of the compressive strength, the damage continued to accumulate and eventually led to internal failure. Meanwhile, the rock samples entered the plastic deformation stage with the release of a considerable amount of AE energy. e internal cracks in the rock samples have developed and penetrated to form macroscopic cracks at the critical failure load. Unloading opened the fracture surface of the internal microstructure of the rock samples, which made the unloading process accompanied by more AE events. e deformation and fracture process of rock included shear crack, tension crack, and tension-shear mixed crack.

AE Characteristics of Rock Samples under Cyclic
Different crack modes were accompanied by AE signals with different characteristics. e average frequency (AF) and the rise angle of the waveforms (RA) were often used to analyze the crack mode of the rock samples [38,39]. As shown in Figure 10, at the initial stage of loading and unloading, the internal cracks in the rock samples gradually closed, resulting in the phenomenon of high RA and low AF. At this time, shear stress played a major role in the rock samples. Subsequently, the phenomenon of high AF and low RA appeared during the second to the seventh cycle of loading. It can be inferred that tensile stress was the main stress during this period and a large number of microcracks began to appear. e microcracks were connected with each other, and the damage inside the rock samples gradually accumulated. At the same time, the RA value had an upward trend as the stress increased. When the critical failure occurred, both RA value and AF value increased to the maximum, and macroscopic cracks appeared under the combined action of tensile stress and shear stress. In addition, it can be seen from Figure 11 that the distribution of RA-AF had changed from dense to scattered. e rock samples had obvious characteristics of low RA and high AF, indicating that the tensile failure of the rock samples was more significant.

Change of AE Felicity Ratio in Cyclic Loading and
Unloading.
e AE phenomenon reflected the development and expansion degree of microcracks in rocks; that is, it was the manifestation of its internal damage. Figures 8 and 9 showed that there was a significant increase in AE even when the stress level was lower than the previous maximum stress level.
is result reflected the Felicity effect of the AE phenomenon of the rock under uniaxial cyclic loading and unloading, which showed the irreversibility of the AE [40,41]. To better describe the irreversibility of rock samples, the Felicity effect was introduced. Felicity ratio is a measure of rock damage and defined as where R F (i) is the Felicity ratio of the ith loading-unloading cycle, σ i is the stress level when AE rings begin to significantly increase in the ith loading-unloading cycle, and σ i−1(max) is the maximum stress level in the (i − 1)th loading-unloading cycle.
In the study of the Felicity effect ratio, there was no uniform standard for the significantly increased AE. According to the guiding principle recommended by CARP, AE count above 20 was studied as the basic value [42]. Figure 12 showed the change in Felicity ratio with the number of cycles.  Figure 12 showed that the Felicity ratio decreased with the increase of the number of cycles, indicating that the internal damage degree of the rock samples had been increasing. As a result, the degree of irreversibility of AE of rock samples continued increasing, which reflected the cumulative effect of rock damage. Felicity ratio was greater than 1 at the initial stage of low stress. It showed that the rock samples were in the compaction stage. e pores and microcracks in the rock samples were gradually closed to generate AE signals, and the damage degree was relatively low at this time. Felicity ratio gradually decreased with the increase of the stress level. For example, for R-4, the ratio decreased from the initial value of 1.27 to 1.05 after the second cycle. R-4 entered the elastic deformation stage after the compaction stage, with a low stress level. e AE characteristic of the rock samples showed the Kaiser effect, and the damage degree was extremely low. e rock samples entered the plastic deformation stage when the stress level further increased. e cracks inside the rock samples continued to develop and penetrate and the internal damage continued to accumulate. Felicity ratio significantly decreased from 1.05 to 0.55 after the third cycle. e average Felicity ratio of the rock samples was 0.54 in the seventh cycle. e damage degree was severe due to the stable development of cracks in the rock samples. e Felicity ratio maintained a decreasing trend after the seventh cycle, but the decreasing trend became slow. At this moment, the rock samples were in the failure stage. e internal cracks rapidly expanded and the corresponding damage degree was maximal.

Calculation of Energy under Uniaxial Compression.
AE technique can be used to obtain information on the form of energy release and the development of crack modes. Recent studies [43][44][45] have shown that there is a certain relationship between crack propagation and emitted energy. In this experimental study, it was found that the red sandstone also had a snap-back phenomenon after the peak stress under the uniaxial compression, and a lot of AE activities would occur during this instability period. e phenomenon was due to the fact that the dissipation through rock material damage was not enough to dissipate all the elastic strain energy stored inside, which caused the unconsumed part of the energy to be emitted suddenly, resulting in the dynamic vibration and propagation of elastic waves. e schematic diagram of the snap-back phenomenon was shown in Figure 13. is emitted energy can be detected by the AE sensors.
According to the calculation method of dissipated energy rate in the article [43], the calculation steps were listed as follows: (i) It was necessary to find the elastic limit in the uniaxial load-displacement curve. (ii) According to the elastic limit, the corresponding time point in the load-time diagram was found, and it was subdivided from this time point. (iii) Each subdivision time point corresponded to a load, and the corresponding load value returned to the load-displacement curve. (iv) Dissipated energy rate was defined by line segments parallel to elastic branches, as shown in the shaded part.
e schematic diagram of calculating the dissipated energy rate was shown in Figure 14. e curve of dissipated energy rate and AE energy rate with respect to loading time was depicted in Figure 15.
As illustrated in Figure 15, the dissipated energy rate and AE energy rate had different change trends. At the beginning of loading, the natural fractures of the rock samples were gradually compacted, and the weak elastic waves continued to be released as the fractures closed. us, there was an obvious increase in the AE energy rate at this time.
ereafter, it entered the stage of elastic deformation. e AE entered a quiet period, while a lower dissipated energy rate appeared. When the rock samples entered the plastic stage, new cracks were constantly produced inside the rock samples. More high-energy AE signals can be collected

Calculation of Energy under Cyclic Loading and
Unloading. In the process of test loading, the work done by the external load on the rock during the entire cyclic loading and unloading process is the total work. According to the law of conservation of energy, the rock and the outside environment are constantly exchanging energy during the entire loading and unloading process, which converts the work done by the external load into elastic strain energy and dissipation energy. As shown in Figure 16, the area sandwiched between the lower part of loading curve OA and the x-axis is the total work done by the external load, that is, input energy density E. e area between the bottom of the unloading curve AB and the xaxis is elastic energy density E e released by the rock sample. e total work done by the external load minus the elastic deformation energy of the rock sample is the dissipated energy density E d , which is the area between the loading and unloading curves, as shown in the shaded part of OAB. e energy density E can be defined as  10 Shock and Vibration where E is the input energy density, MJ/mm 3 ; E e is the elastic energy density, MJ/mm 3 ; E d is the dissipated energy density, MJ/mm 3 . Elastic energy density E e and dissipated energy density E d released by the rock sample in each cycle can be calculated by calculating the area.

Energy Evolution Law of Rock Samples.
According to the above energy calculation method and test curve, the elastic energy density and dissipated energy density of the three rock samples were calculated and shown in Tables 2-4. e proportion of elastic energy density E e to input energy density E is defined as elastic energy ratio R e . e ratio of dissipated energy density E d to input energy density E is defined as dissipated energy ratio R d ; equations (3) and (4) are as follows: Tables 2-4, which were the development curves of the elastic energy density and dissipated energy density at different stages of rock samples R-4, R-5, and R-6.

Figures 17(a)-17(c) are drawn from the data in
In Figures 17(a)-17(c), the three samples had very similar change trends of elastic energy density. e curves were relatively gentle and showed a nonlinear growth with a relatively slow growth rate in the initial compaction stage, as the elastic energy density stored in the rock samples was gradually released during unloading. e rock samples entered the linear elastic stage after the compaction stage, during which the elastic energy density was released again during unloading. It showed a linear growth with a faster growth rate. e elastic energy density reached the maximum and began to release when the stress was maximal.
us, most of the work done by the external force was converted into elastic energy and stored in the rock samples during the compaction and elastic stages. In addition, the dissipated energy density of the three rock samples first slowly increased with the increase of the loading stress. e dissipated energy density began to gradually increase when the microcracks in the rock samples gradually generated, developed, steadily expanded, and entered the stage of stable fracture development. e dissipated energy density of the rock samples increased in a positive correlation with the increase of the loading stress, indicating that a greater loading stress corresponded to a greater dissipation energy. e internal cracks in the rock samples had penetrated and formed macroscopic cracks when the rock samples were close to failure. A lot of energy was consumed in the process and the dissipation energy density significantly increased. e elastic energy stored in the rock samples at the initial stage was released in a large amount and converted into dissipated energy. When the rock samples were finally broken, a crisp sound was made.

Energy Distribution Law of Rock Samples.
Energy dissipation will cause damage to the rock, and energy release is the inherent reason for the sudden destruction of the entire     rock [46,47]. To better explore the changes in energy during the deformation and failure process of red sandstone samples under cyclic loading and unloading, the changes in elastic energy ratio and dissipated energy ratio were analyzed. Figures 18 and 19 were obtained from the data in Tables 2-4, which showed the relationships between elastic energy ratio, dissipated energy ratio, and axial stress. e elastic energy ratio nonlinearly changed with the stress during the cyclic loading and unloading process of the red sandstone samples. In the initial stage of loading, the elastic energy ratio sharply increased with the increase in stress.
e crack entered the stage of stable propagation when the axial stress approached approximately 40% of the peak strength, and the growth rate of the elastic energy ratio gradually decreased. en the crack entered the stage of unstable crack propagation when the load reached the peak strength level of 65∼80%, and the growth rate of elastic energy ratio further decreased. e elastic energy ratio slightly decreased near the failure of the samples. However, the dissipated energy ratio had been decreasing before the failure, and it had a slight increase as it approached failure.
Most of the work done by external forces had been converted into elastic energy at the initial stage of loading, but the difference between the two was very small due to the microcrack closure inside the samples, and the friction and the slip among particles consumed a lot of energy. It entered the linear elastic deformation stage and stable development stage of microfracture as the axial stress increased, and most of the pores in the rock samples have been compacted. Meanwhile, new microcrack initiation resulted in the dissipation of a small amount of energy. e microcracks inside the rock samples expanded, connected, and formed macrocracks as the failure approaches, which must consume more dissipated energy so that the dissipated energy ratio increased.

Analysis of Damage Evolution Based on Dissipated
Energy. e internal microcracks of the loaded rock were first compacted, then reextended, and penetrated until it was fractured. e whole process was always accompanied by energy release and dissipation and always followed the law of conservation of energy. e energy dissipated during the loading process was mainly used to form damage and caused the loss of rock strength. is paper defined the damage variable based on the irreversible dissipated energy during the deformation of the rock material [46], aiming to study the characteristics of damage evolution during the deformation and failure of red sandstone under cyclic loading and unloading conditions. Its definition is listed as equations (5) and (6). e change curve of damage variable with loading time is shown in Figure 20.
where D (i) is a single-cycle damage variable; U d(i) is the dissipated energy of single-cycle loading and unloading; U d is the total dissipated energy of destruction under cyclic loading and unloading; D is the cumulative damage variable; i is the number of cycles.
From the above figure, it was found that the damage evolution of the rock samples changed from slow to fast. Due to the slow development of internal cracks in the rock samples at the beginning of loading, the damage variable basically increased at a uniform low rate. When loaded to the fifth cycle, the damage accounted for 37% of the total damage, and the damage of the rock samples started to grow faster. As the cracks inside the rock samples developed and connected, the growth rate of the damage variable was further accelerated, indicating that the degree of rock damage became more serious. When the load reached the seventh cycle, the internal cracks were connected to each other, and the degree of rock damage was close to failure. Subsequently, the damage variable reached its maximum value, and the rock samples were completely destabilized and destroyed.

Conclusions
In this paper, the cyclic loading and unloading tests were performed to comprehensively understand the deformation and strength characteristics of red sandstone under cyclic loading and unloading from the perspective of AE and energy theory. e following conclusions are obtained: (1) Compared with the compaction stage where there were only microcracks in the uniaxial compression test, the microcracks inside the samples were repeatedly closed under the action of cyclic loading and unloading, which had a certain strengthening effect on the compressive strength of the rock samples. (2) When the number of loading cycles increased, the hysteresis loop continuously migrated forward during the cyclic loading and unloading process of the rock samples. It gradually moved in the direction of increasing stress, and its area was increased, indicating that the plastic deformation of rock samples increased with the increase of the number of cycles. (3) e AE count and AE energy significantly increased when the load reached 54% of the compressive strength of the rock samples. e damage continued to accumulate, which caused internal damage. rough the analysis of changes in RA and AF, it was found that tensile failure in the rock samples was more significant under cyclic loading and unloading.
e Felicity ratio continuously decreased with the increase of the stress level. e degree of internal damage of the rock sample was gradually accumulating, which made the irreversible degree of AE of rock samples continue to increase. (4) e dissipated energy rate and the AE energy rate under uniaxial compression had different changes.
In the cyclic loading and unloading test, most of the work done by external forces was converted into elastic energy and stored inside the rock samples in the compaction and elastic stages of rock loading. e dissipation energy slowly increased with the stress at the beginning, and it significantly increased when the rock samples were near the failure. e elastic energy ratio slightly decreased when the samples were close to failure, while the dissipated energy ratio changed in the opposite manner. Based on the damage analysis of the dissipated energy, it was found that the damage evolution of rock samples changed from slow to fast during cyclic loading and unloading.

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

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