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Main Authors: Feldmeier, Johannes, Liu, Yu-Jie, Lukin, Mikhail D., Choi, Soonwon
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.10119
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author Feldmeier, Johannes
Liu, Yu-Jie
Lukin, Mikhail D.
Choi, Soonwon
author_facet Feldmeier, Johannes
Liu, Yu-Jie
Lukin, Mikhail D.
Choi, Soonwon
contents Preparing algebraically correlated ground states of quantum many-body systems is an important, yet challenging task for quantum simulation. We introduce a protocol that employs local projective measurements and unitary feedback for frustration-free gapless systems. Our approach prepares a priori unknown ground states in time that scales polynomially with system size. We analytically show the performance our protocol for the dynamics of a single-particle; we argue the same mechanism generalizes to many-body systems based on the physics of quasiparticles. Our theory predicts that a transient cooling dynamics directly reveals the system's universal critical properties. In particular, the state preparation time is linear in the inverse of the finite-size gap (up to log correction) when the system's dynamical critical exponent is larger or equal the effective spatial dimension explored by the quasiparticles. We verify these predictions in numerical simulations of ferromagnetic Heisenberg models in one- and two dimensions, a Fredkin spin chain, and a two-dimensional model of resonating valence bond states. Our protocol stabilizes gapless many-body ground states fully digitally without requiring analog rotations, enabling access to high-fidelity states beyond conventional adiabatic approaches in near-term experiments.
format Preprint
id arxiv_https___arxiv_org_abs_2603_10119
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Digital dissipative state preparation for frustration-free gapless quantum systems
Feldmeier, Johannes
Liu, Yu-Jie
Lukin, Mikhail D.
Choi, Soonwon
Quantum Physics
Quantum Gases
Preparing algebraically correlated ground states of quantum many-body systems is an important, yet challenging task for quantum simulation. We introduce a protocol that employs local projective measurements and unitary feedback for frustration-free gapless systems. Our approach prepares a priori unknown ground states in time that scales polynomially with system size. We analytically show the performance our protocol for the dynamics of a single-particle; we argue the same mechanism generalizes to many-body systems based on the physics of quasiparticles. Our theory predicts that a transient cooling dynamics directly reveals the system's universal critical properties. In particular, the state preparation time is linear in the inverse of the finite-size gap (up to log correction) when the system's dynamical critical exponent is larger or equal the effective spatial dimension explored by the quasiparticles. We verify these predictions in numerical simulations of ferromagnetic Heisenberg models in one- and two dimensions, a Fredkin spin chain, and a two-dimensional model of resonating valence bond states. Our protocol stabilizes gapless many-body ground states fully digitally without requiring analog rotations, enabling access to high-fidelity states beyond conventional adiabatic approaches in near-term experiments.
title Digital dissipative state preparation for frustration-free gapless quantum systems
topic Quantum Physics
Quantum Gases
url https://arxiv.org/abs/2603.10119