English

Realizing a dynamical topological phase in a trapped-ion quantum simulator

Quantum Physics 2022-08-23 v1 Disordered Systems and Neural Networks Quantum Gases Statistical Mechanics Strongly Correlated Electrons

Abstract

Nascent platforms for programmable quantum simulation offer unprecedented access to new regimes of far-from-equilibrium quantum many-body dynamics in (approximately) isolated systems. Here, achieving precise control over quantum many-body entanglement is an essential task for quantum sensing and computation. Extensive theoretical work suggests that these capabilities can enable dynamical phases and critical phenomena that exhibit topologically-robust methods to create, protect, and manipulate quantum entanglement that self-correct against large classes of errors. However, to date, experimental realizations have been confined to classical (non-entangled) symmetry-breaking orders. In this work, we demonstrate an emergent dynamical symmetry protected topological phase (EDSPT), in a quasiperiodically-driven array of ten 171Yb+^{171}\text{Yb}^+ hyperfine qubits in Honeywell's System Model H1 trapped-ion quantum processor. This phase exhibits edge qubits that are dynamically protected from control errors, cross-talk, and stray fields. Crucially, this edge protection relies purely on emergent dynamical symmetries that are absolutely stable to generic coherent perturbations. This property is special to quasiperiodically driven systems: as we demonstrate, the analogous edge states of a periodically driven qubit-array are vulnerable to symmetry-breaking errors and quickly decohere. Our work paves the way for implementation of more complex dynamical topological orders that would enable error-resilient techniques to manipulate quantum information.

Keywords

Cite

@article{arxiv.2107.09676,
  title  = {Realizing a dynamical topological phase in a trapped-ion quantum simulator},
  author = {Philipp T. Dumitrescu and Justin Bohnet and John Gaebler and Aaron Hankin and David Hayes and Ajesh Kumar and Brian Neyenhuis and Romain Vasseur and Andrew C. Potter},
  journal= {arXiv preprint arXiv:2107.09676},
  year   = {2022}
}

Comments

6+12 pages; 3+7 figures

R2 v1 2026-06-24T04:22:25.548Z