Exact many-body scars and their stability in constrained quantum chains

Quantum scars are nonthermal eigenstates characterized by low entanglement entropy, initially detected in systems subject to nearest-neighbor Rydberg blockade, the so-called PXP model. While most of these special eigenstates elude an analytical description and seem to hybridize with nearby thermal e...

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Bibliographic Details
Published in:Physical review. B 2021-03, Vol.103 (10), p.1, Article 104302
Main Authors: Surace, Federica Maria, Votto, Matteo, Lazo, Eduardo Gonzalez, Silva, Alessandro, Dalmonte, Marcello, Giudici, Giuliano
Format: Article
Language:English
Subjects:
Eigenvectors
Entanglement
Perturbation theory
Scars
Stability
Thermalization (energy absorption)
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Summary:Quantum scars are nonthermal eigenstates characterized by low entanglement entropy, initially detected in systems subject to nearest-neighbor Rydberg blockade, the so-called PXP model. While most of these special eigenstates elude an analytical description and seem to hybridize with nearby thermal eigenstates for large systems, some of them can be written as matrix product states with size-independent bond dimension. We study the response of these exact quantum scars to perturbations by analyzing the scaling of the fidelity susceptibility with system size. We find that some of them are anomalously stable at first order in perturbation theory, in sharp contrast to the eigenstate thermalization hypothesis. However, this stability seems to break down when all orders are taken into account. We further investigate models with larger blockade radius and find a set of exact quantum scars that we write down analytically and compare with the PXP exact eigenstates. We show that they exhibit the same robustness against perturbations at first order.
ISSN:2469-9950
2469-9969
DOI:10.1103/PhysRevB.103.104302