Localization and melting of interfaces in the two-dimensional quantum Ising model

Federico Balducci, Andrea Gambassi, Alessio Lerose, Antonello Scardicchio, Carlo Vanoni

Published 2022-03-17Version 1

We consider the non-equilibrium dynamics of the two-dimensional quantum Ising model in the regime of strong ferromagnetic coupling. We identify large bubbles of polarized spins as a natural basis of states, as it happens in a false-vacuum decay scenario, and study the dynamics of the domain wall delimiting a bubble as an effective one-dimensional quantum-fluctuating interface. We introduce a "holographic" mapping from a sufficiently smooth interface onto a chain of fermionic excitations, and show that their Hamiltonian has an emergent integrability. We find that this integrability is broken by interactions between corners of a finite bubble and by corrections due to a large but finite ferromagnetic coupling, and bound from below the timescales after which the interface of a bubble is ultimately expected to melt. Remarkably, we demonstrate that a nonvanishing longitudinal field gives rise to a robust form of ergodicity breaking in the two-dimensional dynamics, a phenomenon underpinned by Stark many-body localization of the emergent fermionic excitations of the interface.