Spontaneous symmetry breaking in open quantum systems: strong, weak, and strong-to-weak

TL;DR

This paper explores how symmetries in open quantum systems can spontaneously break into strong or weak forms, revealing new phases, gapless modes, and potential time crystalline order, with broad implications for understanding quantum dynamics.

Contribution

It introduces a comprehensive framework for analyzing spontaneous symmetry breaking in open quantum systems, including models, scenarios, and physical consequences of strong and weak symmetry breaking.

Findings

Strong symmetry always spontaneously breaks, either fully or into weak symmetry.

Strong-to-weak symmetry breaking in U(1) systems leads to gapless Goldstone modes and charge diffusion.

Weak U(1) symmetry breaking can induce time crystalline order.

Abstract

Depending on the coupling to the environment, symmetries of open quantum systems manifest in two distinct forms, the strong and the weak. We study the spontaneous symmetry breaking among phases with strong symmetry, weak symmetry, and no symmetry. Concrete Liouvillian models with strong and weak symmetry are constructed, and different scenarios of symmetry-breaking transitions are investigated from complementary approaches. It is demonstrated that strong symmetry always spontaneously breaks, either completely, or into the corresponding weak symmetry. For strong $U(1)$ symmetry, we show that strong-to-weak symmetry breaking leads to gapless Goldstone modes dictating diffusion of the symmetry charge in translational invariant systems. We conjecture that this relation among strong-to-weak symmetry breaking, gapless modes, and symmetry-charge diffusion is general for continuous symmetries. It can be interpreted as an ingappability condition for Lindbladian with strong $U(1)$ symmetry and weak translation symmetry, according to which the gapless spectrum does not require non-integer filling. We also investigate the scenario where the strong symmetry breaks completely. In the symmetry-broken phase, we identify an effective Keldysh action with two Goldstone modes, describing fluctuations of the order parameter and diffusive hydrodynamics of the symmetry charge, respectively. We show that weak $U(1)$ SSB naturally leads to time crystalline order. For a particular model studied here, we uncover a transition from a symmetric phase with a ``Bose surface'' to a symmetry-broken phase with long-range order induced by tuning the filling. Our work outlines the typical scenarios of spontaneous symmetry breaking in open quantum systems, puts forward a theoretical framework to characterize them, and highlights their physical consequences.