Coercivity Landscape Characterizes Dynamic Hysteresis

Abstract

Hysteresis, with rich dynamical behaviors-especially in interacting systems-has drawn broad research interest. Yet its dynamic scalings across time scales lack a unified description, and their transitions remain unclear. Here, we study the stochastic ϕ4 model driven periodically by an external field H. For large systems with small noise strength σ, we find the coercivity Hc H(ϕ=0) sequentially exhibits distinct behaviors with increasing driving rate vH: vH-scaling increase, stable plateau (vH0), vH1/2-scaling increase, and abrupt decline to disappearance. The plateau reflects the competition between thermodynamic and quasi-static limits, namely, σ 0vH 0Hc = 0, and vH 0σ 0Hc=H*. Here, H* is exactly the field-driven first-order phase transition point. In the post-plateau regime, (Hc - HP) scales with (vH - vP)2/3 with vP and HP being the reference points of the plateau. Moreover, we reveal a finite-size scaling for the coercivity plateau as vPσ2 and (H*-HP)σ4/3 by utilizing renormalization-group theory. Our work provides a panoramic view of finite-time scalings of the hysteresis and offers new insights into finite-time/finite-size effect interplay in non-equilibrium systems.