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Realizing Altermagnetism in Fermi-Hubbard Models with Ultracold Atoms

Purnendu Das, Valentin Leeb, Johannes Knolle, Michael Knap

2024Physical Review Letters67 citationsDOI

Abstract

Altermagnetism represents a type of collinear magnetism, that is in some aspects distinct from ferromagnetism and from conventional antiferromagnetism. In contrast to the latter, sublattices of opposite spin are related by spatial rotations and not only by translations and inversions. As a result, altermagnets have spin-split bands leading to unique experimental signatures. Here, we show theoretically how a d-wave altermagnetic phase can be realized with ultracold fermionic atoms in optical lattices. We propose an altermagnetic Hubbard model with anisotropic next-nearest neighbor hopping and obtain the Hartree-Fock phase diagram. The altermagnetic phase separates in a metallic and an insulating phase and is robust over a large parameter regime. We show that one of the defining characteristics of altermagnetism, the anisotropic spin transport, can be probed with trap-expansion experiments.

Topics & Concepts

Fermi Gamma-ray Space TelescopeHubbard modelPhysicsUltracold atomCondensed matter physicsAtomic physicsQuantum mechanicsQuantumSuperconductivityCold Atom Physics and Bose-Einstein CondensatesQuantum many-body systemsTopological Materials and Phenomena
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