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Main Authors: Angkhanawin, Toonyawat, Deger, Aydin, Pritchard, Jonathan D., Adams, C. Stuart
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.08598
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author Angkhanawin, Toonyawat
Deger, Aydin
Pritchard, Jonathan D.
Adams, C. Stuart
author_facet Angkhanawin, Toonyawat
Deger, Aydin
Pritchard, Jonathan D.
Adams, C. Stuart
contents Neutral atom arrays have emerged as a versatile candidate for the embedding of hard classical optimization problems. Prior work has focused on mapping problems onto finding the maximum independent set of weighted or unweighted unit disk graphs. In this paper we introduce a new approach to solving natively-embedded vertex graph coloring problems by performing coherent annealing with Rydberg-qudit atoms, where different same-parity Rydberg levels represent a distinct label or color. We demonstrate the ability to robustly find optimal graph colorings for chromatic numbers up to the number of distinct Rydberg states used, in our case $k=3$. We analyze the impact of both the long-range potential tails and residual inter-state interactions, proposing encoding strategies that suppress errors in the resulting ground states. We discuss the experimental feasibility of this approach and propose extensions to solve higher chromatic number problems, providing a route towards direct solution of a wide range of real-world integer optimization problems using near-term neutral atom hardware.
format Preprint
id arxiv_https___arxiv_org_abs_2504_08598
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Graph Coloring via Quantum Optimization on a Rydberg-Qudit Atom Array
Angkhanawin, Toonyawat
Deger, Aydin
Pritchard, Jonathan D.
Adams, C. Stuart
Quantum Physics
Atomic Physics
Neutral atom arrays have emerged as a versatile candidate for the embedding of hard classical optimization problems. Prior work has focused on mapping problems onto finding the maximum independent set of weighted or unweighted unit disk graphs. In this paper we introduce a new approach to solving natively-embedded vertex graph coloring problems by performing coherent annealing with Rydberg-qudit atoms, where different same-parity Rydberg levels represent a distinct label or color. We demonstrate the ability to robustly find optimal graph colorings for chromatic numbers up to the number of distinct Rydberg states used, in our case $k=3$. We analyze the impact of both the long-range potential tails and residual inter-state interactions, proposing encoding strategies that suppress errors in the resulting ground states. We discuss the experimental feasibility of this approach and propose extensions to solve higher chromatic number problems, providing a route towards direct solution of a wide range of real-world integer optimization problems using near-term neutral atom hardware.
title Graph Coloring via Quantum Optimization on a Rydberg-Qudit Atom Array
topic Quantum Physics
Atomic Physics
url https://arxiv.org/abs/2504.08598