Strategies for digital quantum simulation of bosons

ORAL

Abstract

Many prominent bosonic simulation problems are thought to be intractable on a classical computer, including the Bose-Hubbard model, quantum photonics, and molecular vibronics. The behavior of such systems would be efficiently studied on a quantum computer. Before such a simulation is performed, one must choose how to encode the bosonic degrees of freedom into a set of qubits. We present a general methodology for encoding truncated bosons into arrays of qubits, and consider several encoding types. We study the quantum operations and qubit counts for local and composite operators. Importantly, we also consider the utility of interconverting between mappings in the middle of a simulation. These methods lower the quantum resource requirements compared to previous encoding strategies, which may allow for larger problems to be simulated on near-term quantum devices.

Presenters

  • Nicolas Sawaya

    • Intel Labs

Authors

  • Nicolas Sawaya

    • Intel Labs

  • Tim Menke

    • Harvard Department of Physics, MIT Research Laboratory of Electronics, MIT Department of Physics, Harvard University, Massachusetts Institute of Technology
    • Massachusetts Institute of Technology MIT
    • Harvard University; Research Laboratory of Electronics, Massachusetts Institute of Technology
    • Physics, MIT

  • Thi Ha Kyaw

    • Computer Science, U Toronto

  • Sonika Johri

    • Intel Corp - Santa Clara
    • Intel Labs

  • Alan Aspuru-Guzik

    • Department of Chemistry and Department of Computer Science, Vector Institute for Artificial Intelligence, CIFAR Senior Fellow, University of Toronto
    • Department of Chemistry, University of Toronto
    • Computer Science, U Toronto

  • Gian Giacomo Guerreschi

    • Intel Corp - Santa Clara
    • Intel Labs