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Suppression of antiferromagnetic order by strain-enhanced frustration in honeycomb cobaltate

Gye-Hyeon Kim, Miju Park, Subhasis Samanta, Uksam Choi, Baekjune Kang, Uihyeon Seo, GwangCheol Ji, Seunghyeon Noh, Deok‐Yong Cho, Jung‐Woo Yoo, Jong Mok Ok, Heung‐Sik Kim, Changhee Sohn

2024Science Advances12 citationsDOIOpen Access PDF

Abstract

Layered honeycomb cobaltates are predicted as promising for realizing the Kitaev quantum spin liquid, a many-body quantum entangled ground state characterized by fractional excitations. However, they exhibit antiferromagnetic ordering at low temperatures, hindering the expected quantum state. We demonstrate that controlling the trigonal distortion of CoO 6 octahedra is crucial to suppress antiferromagnetic order through enhancing frustration in layered honeycomb cobaltates. Using heterostructure engineering on Cu 3 Co 2 SbO 6 thin films, we adjust the trigonal distortion of CoO 6 octahedra and the resulting trigonal crystal field. The original Néel temperature of 16 kelvin in bulk Cu 3 Co 2 SbO 6 decreases (increases) to 7.8 kelvin (22.7 kelvin) in strained Cu 3 Co 2 SbO 6 films by decreasing (increasing) the magnitude of the trigonal crystal fields. The first-principles calculation suggests the enhancement of geometrical frustration as the origin of the suppression of antiferromagnetism. This finding supports the potential of layered honeycomb cobaltate heterostructures and strain engineering in realizing extremely elusive quantum phases of matter.

Topics & Concepts

AntiferromagnetismCondensed matter physicsFrustrationGround stateHoneycombMaterials scienceHeterojunctionOctahedronChemistryPhysicsCrystallographyCrystal structureQuantum mechanicsComposite materialAdvanced Condensed Matter PhysicsPhysics of Superconductivity and MagnetismMagnetic and transport properties of perovskites and related materials
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