Strong zero modes in integrable spin-S chains
Fabian H.L. Essler, Paul Fendley, Eric Vernier
TL;DR
This paper derives exact strong zero mode operators for integrable spin-S chains, revealing their edge coherence properties and connection to quantum phase transitions.
Contribution
It introduces a method to construct strong zero modes in integrable spin-S chains, extending previous results and analyzing their locality and phase transition implications.
Findings
ESZM operators are derived for spin-S chains with boundary fields.
These operators imply infinite edge coherence times near the chain boundaries.
The paper connects ESZMs to Bethe ansatz solutions for S=1/2.
Abstract
We derive exact strong zero mode (ESZM) operators for integrable spin-S chains with open boundary conditions and a boundary field. Their locality properties are generally weaker than in the previously known cases, but they still imply infinite coherence times in the vicinity of the edges. We explain how such integrable chains possess multiple ground states describing a first-order quantum phase transition, and that the odd number of such states for integer S makes the weaker locality properties necessary. We make contact with more traditional approaches by showing how the ESZM for S=1/2 acts on energy eigenstates given by solutions of the Bethe equations.
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