PRX Quantum (Aug 2022)

Holographic Simulation of Correlated Electrons on a Trapped-Ion Quantum Processor

  • Daoheng Niu,
  • Reza Haghshenas,
  • Yuxuan Zhang,
  • Michael Foss-Feig,
  • Garnet Kin-Lic Chan,
  • Andrew C. Potter

DOI
https://doi.org/10.1103/PRXQuantum.3.030317
Journal volume & issue
Vol. 3, no. 3
p. 030317

Abstract

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We develop holographic quantum simulation techniques to prepare correlated electronic ground states in quantum matrix-product-state (QMPS) form, using far fewer qubits than the number of orbitals represented. Our approach starts with a holographic technique to prepare a compressed approximation to electronic mean-field ground states, known as fermionic Gaussian matrix-product states (GMPSs), with a polynomial reduction in qubit and (in select cases gate) resources compared to existing techniques. Correlations are then introduced by augmenting the GMPS circuits in a variational technique, which we denote GMPS+X. We demonstrate this approach on Quantinuum’s System Model H1 trapped-ion quantum processor for one-dimensional (1D) models of correlated metal and Mott-insulating states. Focusing on the 1D Fermi-Hubbard chain as a benchmark, we show that GMPS+X methods faithfully capture the physics of correlated electron states, including Mott insulators and correlated Luttinger liquid metals, using considerably fewer parameters than problem-agnostic variational circuits.