Dynamical Freezing and Scar Points in Strongly Driven Floquet Matter: Resonance vs Emergent Conservation Laws

We consider a clean quantum system subject to strong periodic driving. The existence of a dominant energy scale,hDx, can generate considerable structure in an effective description of a system that, in the absence of the drive, is nonintegrable and interacting, and does not host localization. In par...

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Bibliographic Details
Published inPhysical review. X Vol. 11; no. 2; p. 021008
Main Authors Haldar, Asmi, Sen, Diptiman, Moessner, Roderich, Das, Arnab
Format Journal Article
LanguageEnglish
Published College Park American Physical Society 07.04.2021
Subjects
Conservation laws
Couplings
Energy absorption
Freezing
Heating
Ising model
Maximum entropy
Perturbation theory
Phases
Physics
Quantum theory
Resonance
Scars
Shaking
Condensed Matter Physics
Quantum Physics
Statistical Physics
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Summary:We consider a clean quantum system subject to strong periodic driving. The existence of a dominant energy scale,hDx, can generate considerable structure in an effective description of a system that, in the absence of the drive, is nonintegrable and interacting, and does not host localization. In particular, we uncover points of freezing in the space of drive parameters (frequency and amplitude). At those points, the dynamics is severely constrained due to the emergence of an almost exact, local conserved quantity, which scars the entire Floquet spectrum by preventing the system from heating up ergodically, starting from any generic state, even though it delocalizes over an appropriate subspace. At large drive frequencies, where a naïve Magnus expansion would predict a vanishing effective (average) drive, we devise instead a strong-drive Magnus expansion in a moving frame. There, the emergent conservation law is reflected in the appearance of the “integrability” of an effective Hamiltonian. These results hold for a wide variety of Hamiltonians, including the Ising model in a transverse field in any dimension and for any form of Ising interaction. The phenomenon is also shown to be robust in the presence of two-body Heisenberg interactions with any arbitrary choice of couplings. Furthermore, we construct a real-time perturbation theory that captures resonance phenomena where the conservation breaks down, giving way to unbounded heating. This approach opens a window on the low-frequency regime where the Magnus expansion fails.
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ISSN:2160-3308
2160-3308
DOI:10.1103/PhysRevX.11.021008