Quantum logic using correlated one-dimensional quantum walks

• dc.contributor.author: Lahini, Yoav
• dc.contributor.author: Steinbrecher, Gregory R
• dc.contributor.author: Bookatz, Adam D
• dc.contributor.author: Englund, Dirk
• dc.date.issued: 2018
• dc.identifier.uri: https://hdl.handle.net/1721.1/134940
• dc.description.abstract: © 2018, The Author(s). Quantum Walks are unitary processes describing the evolution of an initially localized wavefunction on a lattice potential. The complexity of the dynamics increases significantly when several indistinguishable quantum walkers propagate on the same lattice simultaneously, as these develop non-trivial spatial correlations that depend on the particle’s quantum statistics, mutual interactions, initial positions, and the lattice potential. We show that even in the simplest case of a quantum walk on a one dimensional graph, these correlations can be shaped to yield a complete set of compact quantum logic operations. We provide detailed recipes for implementing quantum logic on one-dimensional quantum walks in two general cases. For non-interacting bosons—such as photons in waveguide lattices—we find high-fidelity probabilistic quantum gates that could be integrated into linear optics quantum computation schemes. For interacting quantum-walkers on a one-dimensional lattice—a situation that has recently been demonstrated using ultra-cold atoms—we find deterministic logic operations that are universal for quantum information processing. The suggested implementation requires minimal resources and a level of control that is within reach using recently demonstrated techniques. Further work is required to address error-correction.
• dc.language.iso: en
• dc.publisher: Springer Nature
• dc.relation.isversionof: 10.1038/S41534-017-0050-2
• dc.source: Nature
• dc.type: Article
• dc.contributor.department: Massachusetts Institute of Technology. Department of Physics
• dc.contributor.department: Massachusetts Institute of Technology. Research Laboratory of Electronics
• dc.relation.journal: npj Quantum Information
• dc.eprint.version: Final published version
• mit.journal.volume: 4
• mit.journal.issue: 1