Dynamic behavior of a magnetic system driven by an oscillatory external temperature
Abstract
The dynamic effects on a magnetic system exposed to a time-oscillating external temperature are studied using Monte Carlo simulations on the classic 2D Ising Model. The time dependence of temperature is defined as T(t)=T0 + A · (2π t/τ). Magnetization M(t) and period-averaged magnetization Q are analyzed to characterize out-of-equilibrium phenomena. Hysteresis-like loops in M(t) are observed as a function of T(t). The area of the loops is well-defined outside the critical Ising temperature (Tc) but takes more time to close it when the system crosses the critical curve. Results show a power-law dependence of Q (the averaged area of loops) on both L and τ, with exponents α=1.0(1) and β=0.70(1), respectively. Furthermore, the impact of shifting the initial temperature T0 on Q is analyzed, suggesting the existence of an effective τ-dependent critical temperature Tc(τ). A scaling law behavior for Q is found on the base of this τ-dependent critical temperature.
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