Entanglement spectroscopy with a depth-two quantum circuit

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 | on systems AB by evaluating the R\'enyi entropy of the reduced state A = TrB(| |). For a k-qubit state (k), the R\'enyi entropy of order n is computed via Tr((k)n), with the complexity growing exponentially in k for classical computers. Johri, Steiger, and Troyer [PRB 96, 195136 (2017)] introduced a quantum algorithm that requires n copies of | and whose depth scales linearly in k*n. Here, we present a quantum algorithm requiring twice the qubit resources (2n copies of | ) but with a depth that is independent of both k and n. Surprisingly this depth is only two gates. Our numerical simulations show that this short depth leads to an increased robustness to noise.