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Quantum simulation of the Haldane phase using open shell molecules

Quantum Gases 2026-03-17 v1 Strongly Correlated Electrons Atomic Physics Quantum Physics

Abstract

Dipolar molecules in optical traps are a versatile platform for studying many-body phases of quantum matter in the presence of strong and long-range interactions. The dipolar interactions in such setups can be enabled by microwave driving opposite parity rotational levels of the molecules. We find that the regime where the N=0,J=1/2,F=1N=0,J=1/2,F=1 state is coupled to the N=1,J=3/2,F=2N=1,J=3/2,F=2 manifold with circularly polarized microwaves, in the presence of a small magnetic field, can lead to spin-1 quantum magnetic Hamiltonians, due to the decoupling between electron spin and orbit, that is unique to the 2Σ^2\Sigma ground state molecules. We demonstrate that in one dimension, the phase diagram associated with this Hamiltonian, computed via tensor network methods, hosts the celebrated Haldane phase. We find that the Haldane phase persists even in the presence of SU(3) correction terms that break the SU(2) algebra of the Hamiltonian. We discuss the feasibility of the proposed scheme for 2Σ^2\Sigma molecules with large rotational constants such as the directly laser cooled molecule MgF for future experiments.

Keywords

Cite

@article{arxiv.2603.14874,
  title  = {Quantum simulation of the Haldane phase using open shell molecules},
  author = {Suman Aich and Ceren B. Dag and H. A. Fertig and Debayan Mitra and Babak Seradjeh},
  journal= {arXiv preprint arXiv:2603.14874},
  year   = {2026}
}

Comments

12 pages, 9 figures

R2 v1 2026-07-01T11:21:35.875Z