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Error suppression in adiabatic quantum computing with qubit ensembles

Quantum Physics 2021-05-18 v2

Abstract

Incorporating protection against quantum errors into adiabatic quantum computing (AQC) is an important task due to the inevitable presence of decoherence. Here we investigate an error-protected encoding of the AQC Hamiltonian, where qubit ensembles are used in place of qubits. Our Hamiltonian only involves total spin operators of the ensembles, offering a simpler route towards error-corrected quantum computing. Our scheme is particularly suited to neutral atomic gases where it is possible to realize large ensemble sizes and produce ensemble-ensemble entanglement. We identify a critical ensemble size NcN_{\mathrm{c}} where the nature of the first excited state becomes a single particle perturbation of the ground state, and the gap energy is predictable by mean-field theory. For ensemble sizes larger than NcN_{\mathrm{c}}, the ground state becomes protected due to the presence of logically equivalent states and the AQC performance improves with NN, as long as the decoherence rate is sufficiently low.

Keywords

Cite

@article{arxiv.1909.09947,
  title  = {Error suppression in adiabatic quantum computing with qubit ensembles},
  author = {Naeimeh Mohseni and Marek Narozniak and Alexey N. Pyrkov and Valentin Ivannikov and Jonathan P. Dowling and Tim Byrnes},
  journal= {arXiv preprint arXiv:1909.09947},
  year   = {2021}
}
R2 v1 2026-06-23T11:22:25.100Z