Subcritical crack growth: the microscopic origin of Paris's law

Abstract

We investigate the origin of Paris's law, which states that the velocity of a crack at subcritical load grows like a power law, da/dt ( K)m, where K is the stress intensity factor amplitude. Starting from a damage accumulation function proportional to (σ)γ, σ being the stress amplitude, we show analytically that the asymptotic exponent m can be expressed as a piecewise-linear function of the %damage accumulation exponent γ, namely, m=6-2γ for γ < γc, and m=γ for γ γc, reflecting the existence of a critical value γc=2. %In this way, here we discover the existence of a critical %value γc=2 characterized by a scaling law with a critical %exponent separating two regimes of different linear functions m %(γ). We performed numerical simulations to confirm this result for finite sizes. Finally, we introduce bounded disorder in the breaking thresholds and find that below γc disorder is relevant, i.e., the exponent m is changed, while above γc disorder is irrelevant.