Physics-Informed Generative Machine Learning for Accelerated Quantum-centric Supercomputing

TL;DR

This paper introduces PIGen-SQD, a physics-informed generative machine learning workflow that enhances quantum-centric supercomputing by improving fermionic state reconstruction, reducing computational costs, and maintaining chemical accuracy on noisy quantum hardware.

Contribution

The work presents a novel integration of physics-informed pruning with generative ML models to improve the robustness and scalability of quantum supercomputing workflows.

Findings

Demonstrated high-fidelity subspace generation on IBM quantum hardware.

Reduced diagonalization costs while maintaining chemical accuracy.

Enhanced robustness of quantum simulations with noisy hardware samples.

Abstract

Quantum centric supercomputing (QCSC) framework, such as sample-based quantum diagonalization (SQD) holds immense promise toward achieving practical quantum utility to solve challenging problems. QCSC leverages quantum computers to perform the classically intractable task of sampling the dominant fermionic configurations from the Hilbert space that have substantial support to a target state, followed by Hamiltonian diagonalization on a classical processor. However, noisy quantum hardware produces erroneous samples upon measurements, making robust and efficient configuration-recovery strategies essential for a scalable QCSC pipeline. Toward this, in this work, we introduce PIGen-SQD, an efficiently designed QCSC workflow that utilizes the capability of generative machine learning (ML) along with physics-informed configuration screening via implicit low-rank tensor decompositions for accurate fermionic state reconstruction. The physics-informed pruning is based on a class of efficient perturbative measures that, in conjunction with hardware samples, provide a substantial overlap with the target state. This distribution induces an anchoring effect on the generative ML models to stochastically explore only the dominant sector of the Hilbert space for effective identification of additional important configurations in a self-consistent manner. Our numerical experiments performed on IBM Heron R2 quantum processors demonstrate this synergistic workflow produces compact, high-fidelity subspaces that substantially reduce diagonalization cost while maintaining chemical accuracy under strong electronic correlations. By embedding classical many body intuitions directly into the generative ML model, PIGen-SQD advances the robustness and scalability of QCSC algorithms, offering a promising pathway toward chemically reliable quantum simulations on utility-scale quantum hardware.