Lower bounds on entanglement entropy without twin copy

Abstract

We discuss the possibility of estimating experimentally the von Neumann entanglement entropy SAvN of a symmetric bi-partite quantum system AB by using the basic measurement counts (bitstrings) for a single copy of a prepared state. Using exact diagonalization and analog simulations performed with the publicly available QuEra facilities for chains and ladders of Rydberg atoms, we calculate the Shannon entropy SABX associated with the bitstrings of adiabatically prepared ground states and the reduced entropies SAX and SBX obtained from the marginal probabilities in A and B. We then calculate the classical mutual information IXAB=SAX+SBX-SABX, which is a lower bound on SAvN. We show that for a broad range of lattice spacing and detuning, IXAB is typically 20 percent below SAvN in regions where SAvN is large and a less close bound in regions where SAvN is low. We argue that this use of the easily available bitstrings provides a robust and efficient way to explore empirically the phase diagram of qubit-based quantum simulators and identify critical regions.

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