Experimental relation between shear strength under low pressure and S-wave velocity of rock subjected to mechanical weathering

Abstract

The reduction in the shear strength of rock exposed on slope surfaces due to mechanical weathering is a ubiquitous phenomenon in regions where extreme environmental conditions prevail, i.e., repeated changes in temperature and moisture. In dealing with the slope instability problems in such regions, the long-term effects of weathering on the strength, deformation and durability characteristics of exposed rock are envisaged in this study. Therefore, in addition to conducting multiple-cycle standard slake durability tests on rock samples taken from the lithologies of Pakistan and Japan, and on artificial soft rock, the decrease in strength and stiffness is also studied by reproducing mechanical weathering in the laboratory. The reproduced laboratory weathering (RLW) is conducted with a new device that enables vacuumed saturation, freezing, thawing, drying and cooling under a maintained level of confining pressure. The decrease in strength, stiffness and durability is elucidated from the test results, which indicate that rock having a very low level of reference strain (shear strength/modulus at small strain) is resistant to RLW and slaking. Intact rock exhibits very low reference strain and this reference strain increases with an increase in the degree of weathering, which is the case of weathered rock. The decrease in the strength of rock is an important property for judging the safety of rock slopes undergoing weathering. Thus, the relation between the strength and the S-wave velocity of rock undergoing weathering is established. The authors recommend the use of this relation for a quick assessment of the strength of rock by briefly measuring the S-wave velocity of the weathered surface layer. The relationship will assist practitioners in quickly screening potentially unstable slopes.