Spatio-temporal characteristics of acoustic emission during the deformation of rock samples with compressional and extensional en-echelon faults
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Abstract
The spatio-temporal characteristics of acoustic emission (AE) during the deformation of rock samples with compressional and extensional en-echelon faults have been studied. The results show that the pre-existing structure can significantly influence the patterns of AE spatial distribution. With increasing of differential stress, AE events firstly cluster around the two ends of pre-existing faults inside the jog and then along the line joining the two ends. The biggish AE events often occur around one end repeatedly. The image of AE clusters indicates the direction and the area of the fracture propagation. The direction of the macroscopic fracture in extensional and compressional jogs is perpendicular and parallel to the direction of axial stress, respectively. The weakening process before the fracturing of jog area is remarkable, and one of the typical precursors for the instability is that the cumulative frequency of AE events increases exponentially. After the fracturing of the jog the frequency and releasing strain energy of AE events decrease gradually. During the friction period, there is no precursory increasing of AE activity before the big stick-slip events. The change of b value in jog shows a typical change of “decreasing tendentiously → returning quickly” before the instability. The decrease of b value occurs in the process of stress increasing and sometime goes down to the weakening stage, and the quick increase b values appears in a short time just before the instability. The comparative analysis shows that the difference in b value due to the different structures is larger than b value variation caused by increase of the differential stress. For the same sample, the temporal sequence of AE is strongly affected by the mechanical state, and the high loading velocity corresponds to the high release rate of strain energy and low b value. Due to its lower failure strength, the broken area is sensitive to small changes in differential stress. Therefore, it offers a potential explanation for the phenomena of “precursory window or sensitive point” and “separation of seismic source and precursors”.
Key words
acoustic emission rock sample compressional en-echelon fault extensional en-echelon fault biaxial experiment differential stressCLC number
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References
- Bomblakis G G. 1973. Study of the brittle fracture process under uniaxial compression [J]. Tectonophysics, 18: 231–248.CrossRefGoogle Scholar
- Chow T M, Meglis I L, Yourg R P. 1995. Progressive microcrack development in tests on Lac du Bonnet Granite—II. Ultrasonic tomographic imaging [J]. Int Rock Mech Min Sci & Geomech Abstr, 32(1): 85–91.CrossRefGoogle Scholar
- DU Yi-jun, MA Jin, LI Jian-guo. 1989. Mutual action of en-echelon cracks and its stability [J]. Chinese J Geophys, 32(Monograph I): 218–231 (in Chinese).Google Scholar
- JIANG Hai-kun. 2000. Characteristics of Acoustic Emission During the Deformation of Rock Samples with Typical Fault Pattern and Samples at High Pressure and Temperature [D]: [PhD Dissertation]. Beijing: Institute of Geology, China Seismological Bureau, 19–27, 30–32, 45–51 (in Chinese).Google Scholar
- JIANG Hai-kun, ZHANG Liu, WANG Qi. 1999. 3-D location of acoustic emission and study on the anisotropic velocity structure in the sample [J]. Earthquake, 19(3): 245–252 (in Chinese).Google Scholar
- JIANG Hai-kun, ZHANG Liu, ZHOU Yong-sheng. 2000. Temporal behavior of AE sequence in deformation and failure process of granite under the condition of different confining pressure [J]. Chinese J Geophys, 43(6): 858–872.Google Scholar
- JIANG Xiu-e, ZHANG Guo-min, SHAN Jing-xiu, et al. 1989. Application of "earthquake windows" in the earthquake forecast [A]. In: XU Shao-xie, LU Yuan-zhong, ZHU Chuan-zhen, et al eds. Corpus of Practical Method for Earthquake Prediction (Monograph for Seismology) [C]. Beijing: Scientific Books and Periodicals Press, 296–311 (in Chinese).Google Scholar
- LI Jian-guo, SHI Gui-mei, MA Jin. 1989. Study on the failed features and instability of jogs [A]. In: Institute of Geology, State Seismological Bureau eds. Modern Study on Movement of Crust (4) [C]. Beijing: Seismological Press, 149–155 (in Chinese).Google Scholar
- LI Shi-yu, TENG Chun-kai, LU Zhen-ye, et al. 2000. The experimental investigation of microcracks nucleation in typical tectonics [J]. Acta Seismologica Sinica, 13(3): 295–305.Google Scholar
- LIU Li-qiang, MA Jin, WU Xiu-fang. 1986. An experiment study on the process of deformation and instability for en-echelon faults [J]. Acta Seismologica Sinica, 8(4): 393–403 (in Chinese).Google Scholar
- MA Sheng-li, DENG Zhi-hui, MA Wen-tao, et al. 1995a. Experiment study on evolution of physical field during deformation of en-echelon faults (I and II) [J]. Seismology and Geology, 17(4): 327–341 (in Chinese).Google Scholar
- MA Wen-tao, MA Jin, LIU Li-qiang, et al. 1995b. The characteristics of acoustic emission in en-echelon structure [J]. Seismology and Geology, 17(4): 342–348 (in Chinese).Google Scholar
- WANG Ze-gao. 1986. On the practice and prospect for the "window" method [J]. Acta Seismologica Sinica, 8(3): 254–262 (in Chinese).Google Scholar
- ZHANG Guo-min, SUN Shi-hong. 1985. Stress release features of aftershock sequences of large earthquakes in North China and their physical explanation [J]. Earthquake, 5(1): 1–7 (in Chinese).Google Scholar
- ZHANG Zhi-li, FANG Xing. 1989. Experimental study on mixed crack extension in the rock plate with asymmetric body [J]. Chinese J Geophys, 32(Monograph I): 183–193 (in Chinese).Google Scholar
- ZHANG Zhi-li, LI Qiang. 1989. Experimental study on the extending process of ruptures and changes of geophysical field [J]. Progress of Geophysics, 8(4): 225–231 (in Chinese).Google Scholar