Anomalous softness in amorphous matter in the reversible plastic regime
Abstract
We study an integer automaton elasto-plastic model of an amorphous solid subject to cyclic shear of amplitude . We focus on the reversible plastic regime at intermediate 0<<y, where, after a transient, the system settles into a periodic limit cycle with hysteretic, dissipative plastic events which repeat after an integer number of cycles. We study the plastic strain rate, dεdγ, (where γ is the applied strain and ε is the plastic strain) during the terminal limit cycles and show that it consists of a creeping regime at low γ with very low dεdγ followed by a sharp transition at a characteristic strain, γ*, and stress, σ*, to a flowing regime with higher dεdγ. We show that while increasing above 0 results in lower terminal ground state energy, Umin, and a correspondingly narrower distribution of stresses, it, surprisingly, results in lower γ*, and σ*. The stress distribution, P(σ), also becomes skewed for >0. That is, the systems in the RPR are anomalously soft and mechanically polarized. We relate this to an emergent characteristic feature in the stress distribution, P(σ), at a value, σ0, which is independent of and show that σ0 implies a relation between the dependence of σ*, γ*, and the amplitude of plastic strain, εp. We show that the onset of hysteresis is characterized by a power-law scaling, indicative of a second order transition with εp (-0)1.20.1. We argue that σ0 and, correspondingly, the onset of the RPR at =0, is simply set by the so-called Eshelby-stress. Furthermore, we show that cycling at 0 results in a maximally hardened state.
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