Universal initial state preparation for first quantized quantum simulations
Abstract
Preparing symmetry-adapted initial states is a principal bottleneck in first-quantized quantum simulation. We present a universal approach that efficiently maps any polynomial-size superposition of occupation-number configurations to the first-quantized representation on a digital quantum computer. The method exploits the Jordan--Schwinger Lie algebra homomorphism, which identifies number-conserving second-quantized operators with their first-quantized action and induces an equivariant bijection between Fock occupations and weight states within the Schur--Weyl decomposition. Operationally, we prepare an encoded superposition of Schur labels via a block-encoded linear combination of unitaries and then apply the inverse quantum Schur transform. The algorithm runs in time for configurations of particles over modes to accuracy , and applies universally to fermions, bosons, and Green's paraparticles in arbitrary single-particle bases. Resource estimates indicate practicality within leading first-quantized pipelines; statistics-aware or faster quantum Schur transforms promise further reductions.
Cite
@article{arxiv.2510.07278,
title = {Universal initial state preparation for first quantized quantum simulations},
author = {Jack S. Baker and Gaurav Saxena and Thi Ha Kyaw},
journal= {arXiv preprint arXiv:2510.07278},
year = {2025}
}
Comments
22 pages, 3 figures, 1 table, 4 algorithms