Quadratic Quantum Variational Monte Carlo
Abstract
This paper introduces the Quadratic Quantum Variational Monte Carlo (Q$^2$VMC) algorithm, an innovative algorithm in quantum chemistry that significantly enhances the efficiency and accuracy of solving the Schrödinger equation. Inspired by the discretization of imaginary-time Schrödinger evolution, Q$^2$VMC employs a novel quadratic update mechanism that integrates seamlessly with neural network-based ansatzes. Our extensive experiments showcase Q$^2$VMC's superior performance, achieving faster convergence and lower ground state energies in wavefunction optimization across various molecular systems, without additional computational cost. This study not only advances the field of computational quantum chemistry but also highlights the important role of discretized evolution in variational quantum algorithms, offering a scalable and robust framework for future quantum research.
Cite
Text
Su and Liu. "Quadratic Quantum Variational Monte Carlo." Neural Information Processing Systems, 2024. doi:10.52202/079017-0698Markdown
[Su and Liu. "Quadratic Quantum Variational Monte Carlo." Neural Information Processing Systems, 2024.](https://mlanthology.org/neurips/2024/su2024neurips-quadratic/) doi:10.52202/079017-0698BibTeX
@inproceedings{su2024neurips-quadratic,
title = {{Quadratic Quantum Variational Monte Carlo}},
author = {Su, Baiyu and Liu, Qiang},
booktitle = {Neural Information Processing Systems},
year = {2024},
doi = {10.52202/079017-0698},
url = {https://mlanthology.org/neurips/2024/su2024neurips-quadratic/}
}