English

Entanglement spectroscopy with a depth-two quantum circuit

Quantum Physics 2019-01-09 v2 Strongly Correlated Electrons

Abstract

Noisy intermediate-scale quantum (NISQ) computers have gate errors and decoherence, limiting the depth of circuits that can be implemented on them. A strategy for NISQ algorithms is to reduce the circuit depth at the expense of increasing the qubit count. Here, we exploit this trade-off for an application called entanglement spectroscopy, where one computes the entanglement of a state ψ| \psi \rangle on systems ABAB by evaluating the R\'enyi entropy of the reduced state ρA=TrB(ψψ)\rho_A = {\rm Tr}_B(| \psi \rangle \langle \psi |). For a kk-qubit state ρ(k)\rho(k), the R\'enyi entropy of order nn is computed via Tr(ρ(k)n){\rm Tr}(\rho(k)^{n}), with the complexity growing exponentially in kk for classical computers. Johri, Steiger, and Troyer [PRB 96, 195136 (2017)] introduced a quantum algorithm that requires nn copies of ψ| \psi \rangle and whose depth scales linearly in knk*n. Here, we present a quantum algorithm requiring twice the qubit resources (2n2n copies of ψ| \psi \rangle) but with a depth that is independent of both kk and nn. Surprisingly this depth is only two gates. Our numerical simulations show that this short depth leads to an increased robustness to noise.

Keywords

Cite

@article{arxiv.1806.08863,
  title  = {Entanglement spectroscopy with a depth-two quantum circuit},
  author = {Yigit Subasi and Lukasz Cincio and Patrick J. Coles},
  journal= {arXiv preprint arXiv:1806.08863},
  year   = {2019}
}

Comments

10 pages, 6 figures

R2 v1 2026-06-23T02:39:02.862Z