Discrete time-crystalline response stabilized by domain-wall confinement
- URL: http://arxiv.org/abs/2110.14705v3
- Date: Thu, 15 Sep 2022 08:02:00 GMT
- Title: Discrete time-crystalline response stabilized by domain-wall confinement
- Authors: Mario Collura and Andrea De Luca and Davide Rossini and Alessio Lerose
- Abstract summary: In this work, we establish the effectiveness of a different mechanism arising in quantum spin chains: the confinement of domain walls into mesonic bound states.
We consider translationally invariant quantum Ising chains periodically kicked at arbitrary frequency, and discuss two possible routes to domain-wall confinement.
We point out the experimental relevance of this new mechanism for stabilizing a long-lived time-temporal response in Rydberg-crystalline spin chains.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Discrete time crystals represent a paradigmatic nonequilibrium phase of
periodically driven matter. Protecting its emergent spatiotemporal order
necessitates a mechanism that hinders the spreading of defects, such as
localization of domain walls in disordered quantum spin chains. In this work,
we establish the effectiveness of a different mechanism arising in clean spin
chains: the confinement of domain walls into ``mesonic'' bound states. We
consider translationally invariant quantum Ising chains periodically kicked at
arbitrary frequency, and discuss two possible routes to domain-wall
confinement: longitudinal fields and interactions beyond nearest neighbors. We
study the impact of confinement on the order parameter evolution by
constructing domain-wall-conserving effective Hamiltonians and analyzing the
resulting dynamics of domain walls. On the one hand, we show that for arbitrary
driving frequency the symmetry-breaking-induced confining potential gets
effectively averaged out by the drive, leading to deconfined dynamics. On the
other hand, we rigorously prove that increasing the range $R$ of spin-spin
interactions $J_{i,j}$ beyond nearest neighbors enhances the order-parameter
lifetime \textit{exponentially} in $R$. Our theory predictions are corroborated
by a combination of exact and matrix-product-state simulations for finite and
infinite chains, respectively. The long-lived stability of spatiotemporal order
identified in this work does not rely on Floquet prethermalization nor on
eigenstate order, but rather on the nonperturbative origin of vacuum-decay
processes. We point out the experimental relevance of this new mechanism for
stabilizing a long-lived time-crystalline response in Rydberg-dressed spin
chains.
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