Exploiting many-body localization for scalable variational quantum simulation

TL;DR

This paper shows that initializing variational quantum algorithms in the many-body localized phase prevents barren plateaus, improves trainability, and enables efficient ground state preparation on noisy hardware.

Contribution

It introduces a novel MBL-based initialization strategy for VQAs, demonstrating improved scalability and trainability through theoretical analysis and experimental validation.

Findings

MBL initialization mitigates barren plateaus in VQAs

Experimental evidence of preserved gradients in a 127-qubit processor

Efficient ground state preparation using MBL regime

Abstract

Variational quantum algorithms (VQAs) represent a promising pathway toward achieving practical quantum advantage on near-term hardware. Despite this promise, for generic, expressive ans\"atze, their scalability is critically hindered by barren plateaus--regimes of exponentially vanishing gradients. We demonstrate that initializing a hardware-efficient, Floquet-structured ansatz within the many-body localized (MBL) phase mitigates barren plateaus and enhances algorithmic trainability. Through analysis of the inverse participation ratio, entanglement entropy, and a novel low-weight stabilizer R\'enyi entropy, we characterize a distinct MBL-thermalization transition. Below a critical kick strength, the circuit avoids forming a unitary 2-design, exhibits robust area-law entanglement, and maintains non-vanishing gradients. Leveraging this MBL regime facilitates the efficient variational preparation of ground states for several model Hamiltonians with significantly reduced computational resources. Crucially, experiments on a 127-qubit superconducting processor provide evidence for the preservation of trainable gradients in the MBL phase for a kicked Heisenberg chain, validating our approach on contemporary noisy hardware. Our findings position MBL-based initialization as a viable strategy for developing scalable VQAs and motivate broader integration of localization into quantum algorithm design.