Litcius/Paper detail

Designing Magnetism in High Entropy Oxides

Alessandro R. Mazza, Elizabeth Skoropata, Yogesh Sharma, Jason Lapano, Thomas Heitmann, Brianna L. Musicó, Veerle Keppens, Zheng Gai, J. W. Freeland, Timothy Charlton, Matthew Brahlek, Adriana Moreo, Elbio Dagotto, Thomas Z. Ward

2022Advanced Science81 citationsDOIOpen Access PDF

Abstract

Abstract In magnetic systems, spin and exchange disorder can provide access to quantum criticality, frustration, and spin dynamics, but broad tunability of these responses and a deeper understanding of strong limit disorder are lacking. Here, it is demonstrated that high entropy oxides present a previously unexplored route to designing materials in which the presence of strong local compositional disorder may be exploited to generate tunable magnetic behaviors—from macroscopically ordered states to frustration‐driven dynamic spin interactions. Single‐crystal La(Cr 0.2 Mn 0.2 Fe 0.2 Co 0.2 Ni 0.2 )O 3 films are used as a model system hosting a magnetic sublattice with a high degree of microstate disorder in the form of site‐to‐site spin and exchange type inhomogeneity. A classical Heisenberg model simplified to represent the highest probability microstates well describes how compositionally disordered systems can paradoxically host magnetic uniformity and demonstrates a path toward continuous control over ordering types and critical temperatures. Model‐predicted materials are synthesized and found to possess an incipient quantum critical point when magnetic ordering types are designed to be in direct competition, this leads to highly controllable exchange bias behaviors previously accessible only in intentionally designed bilayer heterojunctions.

Topics & Concepts

MagnetismFrustrationCondensed matter physicsAntiferromagnetismExchange biasHeisenberg modelQuantumMaterials sciencePhysicsMagnetizationMagnetic fieldQuantum mechanicsMagnetic anisotropyMagnetic and transport properties of perovskites and related materialsHigh Entropy Alloys StudiesAdvanced Condensed Matter Physics