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Three types of rock specimens, three-point bending specim en , anti-symmetric four-point bending specimen and direct shearing specimen, wer e used to achieve Mode Ⅰ, Mode Ⅱ and mixed mode Ⅰ-Ⅱ fracture, respectively . Microscopic characteristics of the three fracture modes of brittle rock were s tudied by SEM technique in order to analyze fracture behaviors and better understand fr acture mechanisms of different fracture modes of brittle rock. Test results show that the microscopic characteristics of different fracture modes correspond to different fracture mechanisms. The surface of Mode Ⅰ fracture has a great numbe r of sparse and steep slip-steps with few tearing ridges and shows strong britt leness. In the surface of Mode Ⅱ fracture there exist many tearing ridges and d ensely distributed parallel slip-steps and it is attributed to the action of sh ear stress. The co-action of tensile and shear stresses results in brittle clea v age planes mixed with streamline patterns and tearing ridges in the surface of m ixed mode Ⅰ-Ⅱ fracture. The measured Mode Ⅱ fracture toughness K ⅡC and mixed mode Ⅰ-Ⅱ fracture toughness K mC are larger than Mode Ⅰ fracture t oughness K ⅠC . K ⅡC is about 3.5 times K ⅠC , a nd K mC is about 1.2 times K ⅠC .
Three types of rock specimens, three-point bending specim en, anti-symmetric four-point bending specimen and direct shearing specimen, wer e used to achieve Mode I, Mode II and mixed mode Ⅰ-Ⅱ fracture, respectively. Microscopic characteristics of the three fracture modes of brittle rock were s tudied by SEM technique in order to analyze fracture behaviors and better understand fr acture mechanisms of different fracture modes of brittle rock. Test results show that the microscopic characteristics of different fracture modes correspond to different fracture mechanisms. surface of Mode Ⅰ fracture has a great numbe r of sparse and steep slip-steps with few tearing ridges and shows strong britt leness. In the surface of Mode Ⅱ fracture there exists many tearing ridges and d ensely distributed parallel slip-steps and it is attributed to the action of sh ear stress. The co-action of tensile and shear strains results in brittle clea v age planes mixed with streamline patte rns and tearing ridges in the surface of m ixed mode Ⅰ-Ⅱ fracture. The measured Mode Ⅱ fracture toughness K Ⅱ C and mixed mode Ⅰ-Ⅱ fracture toughness K mC are larger than Mode Ⅰ fracture t oughness K ⅠC. K ⅡC is about 3.5 times K IC, a nd K mC is about 1.2 times K IC.