Abstract
The quantitative determination of crack damage stress is of significant importance for investigating rock deformation and failure. In this study, a new quantitative method for determining the crack damage stress of rock materials was proposed based on acoustic emission (AE) signal detection. Ten rock materials were subjected to uniaxial compression testing, during which real-time AE signals and axial, lateral, and volumetric strain values were recorded. The AE cumulative count curves of the different rock materials were calculated based on the AE counts. These curves were divided into three stages as the axial stress increased: the slowly increasing stage, the steady stage, and the sharply increasing stage. The point where the sharply increasing stage began was defined as the PR point and could be accurately determined based on a fitting optimization method. Then, the damage stress was calculated by using the crack volumetric strain model. Finally, the relationship between the R stress (axial stress corresponding to the PR point) and the crack damage stress was investigated for the ten rock materials. The results showed that there was a good correspondence between the R stress and the crack damage stress. Hence, the R stress can be used to determine the crack damage stress and the starting point of the unstable crack growth stage in rock materials.
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Introduction
The failure process of rock materials is controlled by the development and evolution of internal microcracks (Martin 1993; Zhou and Wang 2016; Pepe et al. 2018; Peng et al. 2018; Wang and Li 2015). The yielding evolution process of rock materials is a macroscopic manifestation of crack initiation and propagation processes (Diederichs et al. 2004; Zhu et al. 2007; Chen et al. 2019). Additionally, the deformation process of rock materials under compressive loading is nonlinear. The process of rock deformation can be roughly divided into four stages based on crack evolution characteristics: the crack closure stage, the no crack initiation stage, the crack initiation and stable propagation stage, and the unstable crack propagation stage. Furthermore, there are several important rock stress thresholds in this process: the crack compaction stress (σcc), crack initiation stress (σci), crack damage stress (σcd), and peak stress (σf), which are characterized as the stress levels corresponding to the end points of the four deformation stages (Diederichs et al. 2004; Zhou et al. 2004 and 2008; Zhou 2005; Martin 1997; Martin and Chandler 1994).
The determination of the above stress thresholds is of great significance for understanding mechanical mechanisms and performing failure predictions for rocks under compression. Extensive laboratory and field investigations have been performed to analyze these thresholds (Martin 1997; Nicksiar and Martin 2013). Martin (1993, 1997) proposed determining σcc, σci, and σcd by using a crack volumetric strain model. They hypothesized that σci can be used to predict the failure of the rock surrounding tunnels. Liu et al. (2009) used a linear regression technique to determine σci and σcd based on the volumetric strain curve of granite under various confining pressures. Nicksiar and Martin (2012) summarized five strain-based methods in laboratory compression tests of σci and σcd and proposed a lateral strain method for low-porosity rocks. Gong and Wu (2019) evaluated the relationships between the crack stress thresholds and the load-unload response ratio curves of ten rock materials. Moreover, they proposed a method for determining σcc and σcd based on the load-unload response ratio theory.
Furthermore, the rock damage and failure process is also associated with acoustic emission (AE) signals. AE detection can capture the AE signals that are generated by the formation of local damage inside rocks, allowing researchers to monitor the rock damage and deformation process (Koerner et al. 1981; Cai et al. 2007a, b; Moradian et al. 2010). Therefore, many researchers have used AE parameters during compression testing to determine the stress thresholds of rock materials (Mlakar et al. 1993; Eberhardt et al. 1997; Eberhardt et al. 1998; Zhang and Wong 2013). Zhou et al. (2014) found that the AE count rate can qualitatively reflect the crack evolution characteristics in different deformation processes and can be used to qualitatively evaluate σci and σcd. Eberhardt et al. (1998) suggested that σci values during laboratory uniaxial compression tests of rock materials could be determined using the AE count method. Furthermore, AE detection parameters can be used to classify crack stress thresholds (Zhou et al. 2019; Zhang et al. 2019). Therefore, more in-depth research is necessary to investigate crack stress thresholds based on AE monitoring parameters (Eberhardt et al. 1998; Huang and Li 2017; Yang et al. 2017).
In the present study, uniaxial compression tests were performed to investigate the engineering properties of ten rock materials. The objectives of these experiments were to determine the crack stress thresholds and understand the damage process in rock materials using AE cumulative count curves. To this end, real-time AE events in the rock materials were captured during uniaxial compression tests. In addition, the relationships between the inflection points in the AE cumulative count curves and the stress thresholds were analyzed and discussed. This work offers a quantitative determination of crack stress thresholds during the rock deformation process.
Crack development in rock materials subjected to uniaxial compression
It is known that the rock material damage process is accompanied by several deformation stages: the compaction stage, the elastic deformation stage, the crack initiation and expansion stage, and the unstable crack propagation stage (Martin 1993, 1997). The crack initiation and expansion stage and unstable crack propagation stage of rock are close to rock failure. Furthermore, the determination of the stress thresholds associated with these deformation stages is significant for rock instability predictions (Cai et al. 2004). Extensive theoretical and experimental studies on the determination of crack stress thresholds have been performed, and various determination methods have been proposed. In the determination of crack stress thresholds, studies have typically been based on fracture mechanics methods (Wei et al. 2017a, b; Du et al. 2020; Liu et al. 2018). Moreover, it is generally understood that the crack volumetric strain model (Martin and Chandler 1994) is the most widely used method for identifying the stress thresholds of rock materials (Eberhardt et al. 1998; Cai et al. 2004; Wang et al. 2012; Wen et al. 2018; Kong et al. 2018).
The main equation for the crack volumetric strain model for uniaxial compression conditions can be written as follows (Martin and Chandler 1994; Eberhardt et al. 1998; Cai et al. 2004; Cai 2010; Wang et al. 2012):
where \( {\varepsilon}_{\mathrm{V}}^e \) is the calculated crack volumetric strain, εV is the volumetric strain, σ1 is the uniaxial stress, and E and ν are the elastic modulus and Poisson’s ratio of the rock material, respectively.
On the basis of Eq. (1), the crack initiation and propagation process of a rock material could be investigated with the calculated crack volumetric strain. Specifically, Fig. 1 shows the axial strain, volumetric strain, and calculated crack volumetric strain of a rock material (taking Yueyang granite as an example) subjected to uniaxial compression conditions. Moreover, the different deformation stages and stress thresholds of Yueyang granite can be accurately distinguished and systematically analyzed as follows.
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(1)
The crack closure stage (I) ends at a stress level of approximately 0.14 times the peak stress of the rock material. Additionally, σcc can be determined from the stress level corresponding to the starting point of the horizontal section based on the calculated crack volumetric strain curve.
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(2)
The axial stress range of the no crack initiation stage (II) is 0.14–0.30σf. The stress-strain curves in this stage maintain a linear relationship. The AE count in this stage is much lower than that in the compaction stage.
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(3)
The initial stress level of the crack initiation and stable propagation stage (III) is defined as σci. In this stage, the AE count begins to increase as the stress increases, which indicates that new microcracks are generated and begin to propagate.
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(4)
The stress level corresponding to the starting point of the unstable crack propagation stage (IV) is identified as σcd. Additionally, σcd is typically defined as the axial stress corresponding to the inflection point of the volumetric strain curve, where the AE count increases sharply (Cai et al. 2004; Wang et al. 2012; Wen et al. 2018; Kong et al. 2018; Cai et al. 2007a, b; Cai 2010).
Test methodologies
Specimen preparation
To investigate the AE characteristics and stress thresholds of different rock materials through uniaxial compression testing, ten rock specimens were selected for this study (Yueyang granite, fine granite, Qingshan granite, red granite, red sandstone, green sandstone, yellow sandstone, Henan limestone, slate, and Leiyang white marble). The ten rock specimens are presented in Fig. 2. All specimens were processed into standard cylinder shapes with dimensions of Φ50 mm × 100 mm, as recommended by the American Society for Testing and Materials. The upper and lower ends of the rock specimens were ground to ensure that they were parallel and smooth.
Test equipment
Uniaxial compression testing was performed on an MTS815 electrohydraulic servo testing machine (MTS, USA), which is shown in Fig. 3. This testing machine is a multifunctional electrohydraulic servo tester that was specially designed for rock testing. Uniaxial compression, triaxial compression, and pore water pressure testing of rock materials can be carried out with this machine. The test system has a maximum load capacity of 4600 kN and can supply a maximum confining stress of 140 MPa.
Test procedure
In the uniaxial compression test, axial compression was applied to the rock specimens with a loading rate of 12 kN/min until the specimens failed. AE transducers (PAC, USA) were used to record AE data during the testing process. The trigger threshold of AE was set to 45 dB for each test, and full waveform data were recorded with a sampling rate of 1 MHz. Two AE transducers were used during the uniaxial compression test. The AE transducer array was symmetrical, and the AE probes were contact with the rock specimens to provide good acoustic coupling between the rock specimens and the sensors.
Testing results
Rock failure modes
In order to analyze the failure modes of different rock materials in uniaxial compression tests, Fig. 4 presents images of the typical failure modes of the ten different rock materials, and Table 1 explicitly summarizes these failure modes.
Conjugate shear failure was the main failure mode of the Yueyang granite and fine granite specimens under uniaxial compression conditions. Additionally, double cones were formed in these rock specimens. Tensile cracks appeared on the surfaces of these rock specimens, and the specimens failed rapidly after reaching the peak stress. This failure was accompanied by ejection phenomena. The main failure mode of the green sandstone and yellow sandstone was internal conjugate shear. A double shear plane was formed in these rock specimens, which was accompanied by fragment ejection when the specimens failed. The main failure mode of the Henan limestone, slate, and Leiyang white marble was open-shear composite failure. Moreover, double cones were also formed in these rock specimens.
AE cumulative count curves in the laboratory compression tests
Representative AE cumulative count curves for the ten rock materials were obtained during the uniaxial compression tests, as shown in Fig. 5. The AE cumulative count curves show clear regularity. With increasing axial strain, the AE cumulative count curves of the rock materials initially increase gently and then remain relatively stable for a time. Finally, the AE cumulative count curves increase sharply as the rock specimens approach failure (Wei et al. 2016). Furthermore, it can be observed that the AE cumulative count curves of the rock materials have two inflection points. The evolution states of the cracks in each rock specimen change after these inflection points, indicating that there is a correlation between the axial stresses corresponding to the inflection points and the stress thresholds of the rock specimens.
Lateral strain and volumetric strain in the laboratory compression tests
Figure 6 illustrates the axial stress-lateral strain curves, axial stress-volumetric strain curves, and volumetric strain-axial strain curves of nine rock materials (the curves of Yueyang granite shown in Fig. 1). There is inflection point in the axial stress-volumetric strain curves of the ten rock materials, and σcd could be determined according to the crack volumetric strain model (Martin and Chandler 1994; Eberhardt et al. 1998; Cai et al. 2004; Wang et al. 2012). Specifically, σcd could be identified based on the inflection points of the axial stress-volumetric strain curves. In addition, after this inflection point, the curves of the rock specimens begin to decrease, and the rock cracks enter the unstable crack development stage (Cai et al. 2004; Cai 2010).
Fitting optimization method
As shown in Fig. 7, the AE cumulative count curves can be roughly divided into the slowly increasing stage (I), the steady stage (II), and the sharply increasing stage (III) as the axial stress increases (Yueyang granite is shown as an example). With increasing axial stress, the AE count decreases because the microcracks in the rock are gradually compressed. However, the AE count is relatively stable in the steady stage of the AE cumulative count curve. In the sharply increasing stage, which follows the steady stage, AE count exhibits a sharply increasing trend with increasing axial stress, indicating that the internal cracks in the rock material have entered the unstable growth stage. Note that there is an inflection point between the steady stage and the sharply increasing stage of the AE cumulative count curves. To better capture and distinguish this inflection point, it is defined as PR point.
To quantitatively determine the PR point of a rock material, we propose a fitting optimization method consisting of the following steps:
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Step 1:
To accurately identify the inflection points of AE cumulative count curves, the data points comprising the AE cumulative count curve are divided into two parts (part I and part II) according to the axial stress (see Fig. 8).
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Step 2:
Part II is fitted by a fourth-degree polynomial, and the fitting function for this part is obtained. If the fitting coefficient of the fitting function is less than 0.996, then the maximum deviation between the fitting line and the AE cumulative count data points is investigated (i.e., the residual between the fitting value and the actual data points in the AE cumulative count curve is calculated).
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Step 3:
The data points in the AE cumulative count curve are reduced in increments of 1% from one end of the maximum deviation between the fitting line and the AE cumulative count data points. The remaining data points are fitted again by a fourth-degree polynomial. This step is repeated until the fitting coefficient of the fitting function is greater than 0.996.
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Step 4:
The first and second derivatives of the fitting formula are calculated. It is known that the second derivative characterizes the concavity and convexity of the fitting curves (Liu et al. 2013).
-
Step 5:
Data point corresponding to the maximum value of the second derivative could be recognized as PR point.
Note that steps of the fitting optimization method could be programmed to determine the PR point more accurately based on a scientific method. Taking the AE cumulative count curve of Yueyang granite as an example, the AE cumulative count curve can be brought into the operation program (illustrated in the Appendix) by using a MATLAB script. When the fitting coefficient is greater than 0.996, the coordinates of the PR point are (183.32, 18486), as shown in Fig. 9.
Relationship between the R stress and the damage stress
In this study, the axial stress corresponding to the PR point was characterized as the R stress (\( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \)). Based on the AE cumulative count curves for the ten rock materials, \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) was generated with the fitting optimization method. Moreover, based on the crack volumetric strain model, σcd is the axial stress corresponding to the inflection point of the axial stress-volumetric strain curve (Martin and Chandler 1994; Martin 1997). Furthermore, it can be concluded that \( {\sigma}_{\mathrm{cd}}^{\mathrm{AE}} \) is largely consistent with the axial stress corresponding to the inflection point of the axial stress-volumetric strain curve (shown in Fig. 10).
Furthermore, to quantitatively investigate the relationship between \( {\sigma}_{\mathrm{S}}^{\mathrm{AE}} \) and σcd, the values of \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) and σcd were determined for each rock specimen. Two rock specimens for each rock material were used in the uniaxial compression tests, and the \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) and σcd values obtained for each rock specimen are listed in Table 2. Moreover, the relative errors between \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) and σcd of the different rock specimens were investigated, and the relative errors are also listed in Table 2.
Additionally, the fitting relationship between \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) and σcd is illustrated in Fig. 11. Figure 11 shows that the fitting equation for \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) and σcd of the ten rock materials is σcd = 1.01σR − 1.37, and the coefficient of determination is 0.964. The coefficient of determination and the slope of the \( {\sigma}_{\mathrm{S}}^{\mathrm{AE}}-{\sigma}_{\mathrm{cd}} \) fitting line are close to 1, which suggests that there is a relatively strong linear relationship between \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) and σcd in the uniaxial compression test. Note that \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) is basically equal to σcd in the uniaxial compression test. Moreover, it can be concluded that \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) could be used to distinguish σcd and the starting point of the dilation stage of rock materials.
Discussion
Eberhardt et al. (1998, 1999) used several approaches to identify crack stress thresholds for rock materials, including the moving point regression method and the AE signal cumulative curve method. The AE signal cumulative curve method is the most frequently used method for determining stress thresholds based on AE signals. According to this method, the rock failure process can be divided into different stages by using an auxiliary line, and then the σcd values of rock materials can be determined (shown in Fig. 12). A specific limitation of this method is that the location of the auxiliary line is greatly influenced by human factors. Additionally, this method cannot quantitatively identify the σcd values of rock materials.
In this work, the \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) values of the rock materials were identified by using a fitting optimization method based on AE cumulative count curves. The proposed method can quantitatively determine the value of σcd by using a rigorous mathematical approach. This method is less affected by human factors than previous methods. Additionally, through continuous monitoring of AE signals, the proposed fitting optimization method can be applied to estimate the deformation states of rock. For example, microseismic (MS) monitoring is similar to “in situ” AE testing, a model based on MS monitoring was proposed by relevant scholars to identify the displacement and damage of bedded rock masses (Li et al. 2020). Drawing on the research results of these scholars, the method proposed in this work also be used to assess the damage degree of rock masses. However, further investigation regarding this application is required.
Conclusions
AE signals are transient elastic waves caused by the development of damage (e.g., cracks) in solid materials under loading (Pestman and Munster 1996; Gong et al. 2019). For the compression process of rock materials, real-time and uninterrupted detection of AE signals can be used to investigate the initiation and development of fractures in rock. Based on the above analysis, the investigation of AE cumulative count was introduced to identify the crack stress thresholds in the rock damage process. Additionally, the relationship between \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) and σcd was analyzed. The following conclusions were drawn from this study:
-
(1)
In this work, the AE signals of ten rock materials were monitored in real-time during uniaxial compression tests. The relationship between the AE counts and the AE cumulative count curves of different rock materials was studied. The results showed that the AE cumulative count curve can be roughly divided into three stages as the axial stress increases: the slowly increasing stage, the steady stage, and the sharply increasing stage.
-
(2)
The inflection point between the steady stage and the sharply increasing stage was identified as the PR point. The PR point of the AE cumulative count curve could be determined based on the fitting optimization method. Moreover, the axial stresses corresponding to the PR point were defined as \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \).
-
(3)
The values of σcd for the ten rock materials were obtained using the crack volumetric strain model. Moreover, the relationship between \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) and σcd was investigated for the ten rock materials. The fitting coefficient of the \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}}-{\sigma}_{\mathrm{cd}} \) fitting line was 0.964, which indicates that there is a clear correspondence between \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) and σcd. Furthermore, \( {\sigma}_{\mathrm{R}}^{\mathrm{AE}} \) can be used to determine the value of σcd and the starting point of the dilation stage of rock materials.
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Funding
This work was supported by the National Natural Science Foundation of China (Grant No. 41877272 and 41472269).
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Appendix
Appendix
Program for the fitting optimization method is as follows:
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Wu, C., Gong, F. & Luo, Y. A new quantitative method to identify the crack damage stress of rock using AE detection parameters. Bull Eng Geol Environ 80, 519–531 (2021). https://doi.org/10.1007/s10064-020-01932-6
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DOI: https://doi.org/10.1007/s10064-020-01932-6