Approximation Algorithms for Quantum Max-$d$-Cut
Abstract
We initiate the algorithmic study of the Quantum Max--Cut problem, a quantum generalization of the well-known Max--Cut problem. The Quantum Max--Cut problem involves finding a quantum state that maximizes the expected energy associated with the projector onto the antisymmetric subspace of two, -dimensional qudits over all local interactions. Equivalently, this problem is physically motivated by the -Heisenberg model, a spin glass model that generalized the well-known Heisenberg model over qudits. We develop a polynomial-time randomized approximation algorithm that finds product-state solutions of mixed states with bounded purity that achieve non-trivial performance guarantees. Moreover, we prove the tightness of our analysis by presenting an algorithmic gap instance for Quantum Max-d-Cut problem with .
Cite
@article{arxiv.2309.10957,
title = {Approximation Algorithms for Quantum Max-$d$-Cut},
author = {Charlie Carlson and Zackary Jorquera and Alexandra Kolla and Steven Kordonowy and Stuart Wayland},
journal= {arXiv preprint arXiv:2309.10957},
year = {2024}
}
Comments
23 + 12 pages