Correlation between avalanches and emitted energies during fracture with variable stress release range

Abstract

We observe the failure process of a fiber bundle model with a variable stress release range, γ, higher the value of γ lower the stress release range. By tuning γ from low to high, it is possible to go from the mean-field (MF) limit of the model to local load sharing (LLS) where local stress concentration plays a crucial role. In the MF limit, the avalanche size s and energy E emitted during the avalanche are highly correlated producing the same distribution for both P(s) and Q(E): a scale-free distribution with a universal exponent -5/2. With increasing γ, the model enters the LLS limit. In this limit, due to the presence of local stress concentration such correlation C(γ) between s and E decreases where the nature of the decreases depends highly on the dimension of the bundle. In 1d, the C(γ) stars from a high value for low γ and decreases towards zero when γ is increased. As a result, Q(E) and P(s) are similar at low γ, an exponential one, and then Q(E) becomes power-law for high-stress release range though P(s) remains exponential. On the other hand, in 2d, the C(γ) decreases slightly with γ but remains at a high value. Due to such a high correlation, the distribution of both s and E is exponential in the LLS limit independent of how large γ is.