Partial Equilibration Scenario in 3D athermal martensites quenched below first-order transition temperatures

Abstract

To test a Partial Equilibration Scenario (PES) of Ritort and colleagues, we do Monte Carlo simulations of discretized-strain spin models, for four 3D martensitic structural transitions under quenches to a bath temperature T <T0 below a first-order transition. The ageing system faces entropy barriers, in searches for energy-lowering passages between quasi-microcanonical energy shells. We confirm the PES signature of an exponential-tail distribution of intermittent heat releases to the bath, scaled in an effective temperature, that in our case, depends on the quench. When its inverse βeff (T) 1/Teff (T) vanishes below a `martensite start' temperature T1 of avalanche conversions, then entropy barriers vanish. When this search temperature Teff (T) vanishes, PES cooling is arrested, as entropy barriers diverge. We find a linear vanishing of Teff(T) Td -T, below a delay-divergence temperature Td in between, T1 < Td < T0. Martensitic conversion delays e1/Teff e1/(Td -T) thus have Vogel-Fulcher-Tammann like divergences. Post-quench delay data extracted from simulations and athermal martensitic alloys, are both consistent with predictions.