Variational LOCC-assisted quantum circuits for long-range entangled states

TL;DR

This paper introduces a hybrid quantum-classical algorithm that optimizes LOCC protocols to efficiently prepare long-range entangled states, reducing circuit depth and improving accuracy over traditional methods.

Contribution

It presents a novel variational approach to find LOCC-assisted circuits for long-range entangled states, with theoretical guarantees and numerical validation.

Findings

Accurately prepares ground states of long-range entangled models

Establishes conditions to avoid barren plateaus in training

Demonstrates practical advantages over unitary circuits

Abstract

Long-range entanglement is an important quantum resource, particularly for topological orders and quantum error correction. In reality, preparing long-range entangled states requires a deep unitary circuit, which poses significant experimental challenges. A promising avenue is offered by replacing some quantum resources with local operations and classical communication (LOCC). With these classical components, one can communicate outcomes of midcircuit measurements in distant subsystems, substantially reducing circuit depth in many important cases. However, to prepare general long-range entangled states, finding LOCC-assisted circuits of a short depth remains an open question. Here, to address this challenge, we propose a quantum-classical hybrid algorithm to find optimal LOCC protocols for preparing ground states of given Hamiltonians. In our algorithm, we introduce an efficient way to estimate parameter gradients and use such gradients for variational optimization. Theoretically, we establish the conditions for the absence of barren plateaus, ensuring trainability at a large system size. Numerically, the algorithm accurately solves the ground state of long-range entangled models, such as the perturbed Greenberger-Horne-Zeilinger state and surface code. Our results demonstrate the advantage of our method over conventional unitary variational circuits: the practical advantage in the accuracy of estimated ground-state energy and the theoretical advantage in creating long-range entanglement.