Acoustic emissions during creep under triaxial compression

Abstract

Granular materials exhibit time- and rate-dependent behaviour resulting from micromechanical processes at the scale of individual particles. Elastic energy is released during these processes and can be detected as acoustic emissions (AE). Using multistage creep tests under isotropic and anisotropic pressure on medium dense samples of dry silica sand, the relationship between the number of AE events NAE and the axial creep strain Ɛa was determined. In addition, the dependence on the mean pressure p and the deviator stress q was investigated. The experimental results show that the development of AE and axial strain during creep are qualitatively comparable. Within the creep phases both the change in Ɛa and NAE can be described by a logarithmic trend with time. The time-dependent development of both measured quantities exhibit a dependence on q. Moreover, the evolution of NAE with time also shows a pronounced increase with increasing p. A time-dependent power law can be assumed to represent the rates of NAE and the rates of Ɛa with time during creep. The exponent m of the power law is similar for all experiments performed. The initial rates of NAE and Ɛa increase with increasing p as well as increasing q/p-ratio. Finally, a linear correlation between log Ɛa and logNAE was found depending on two state parameters a and b, with a seems to be independent on the stress state.