Litcius/Paper detail

High-Entropy van der Waals Materials Formed from Mixed Metal Dichalcogenides, Halides, and Phosphorus Trisulfides

Tianping Ying, Tongxu Yu, Yu-Shien Shiah, Changhua Li, Jiang Li, Yanpeng Qi, Hideo Hosono

2021Journal of the American Chemical Society115 citationsDOIOpen Access PDF

Abstract

The charge, spin, and composition degrees of freedom in a high-entropy alloy endow it with tunable valence and spin states, infinite combinations, and excellent mechanical performance. Meanwhile, the stacking, interlayer, and angle degrees of freedom in a van der Waals material bring to it exceptional features and technological applications. Integration of these two distinct material categories while keeping their merits would be tempting. On the basis of this heuristic thinking, we design and explore a new range of materials (i.e., dichalcogenides, halides, and phosphorus trisulfides) with multiple metallic constitutions and intrinsic layered structure, which are coined as high-entropy van der Waals materials. Millimeter-scale single crystals with a homogeneous element distribution can be efficiently acquired and easily exfoliated or intercalated in this materials category. Multifarious physical properties such as superconductivity, magnetic ordering, metal-insulator transition, and corrosion resistance have been exploited. Further research based on the concept of high-entropy van der Waals materials will enrich the high-throughput design of new systems with intriguing properties and practical applications.

Topics & Concepts

van der Waals forceChemistryVan der Waals radiusDegrees of freedom (physics and chemistry)Valence (chemistry)Van der Waals surfaceVan der Waals strainChemical physicsMetalHomogeneousSpin (aerodynamics)Intermolecular forceAlloyHamaker constantNanotechnologyPhosphorusMaterial propertiesLondon dispersion forceComputational chemistryTransition metalThermodynamicsNon-covalent interactionsCrystallographyCovalent bondCondensed matter physics2D Materials and ApplicationsHigh Entropy Alloys StudiesMXene and MAX Phase Materials