Searching for hexagonal analogues of the half-metallic half-Heusler XYZ compounds

TL;DR

This paper explores the potential of hexagonal analogues of half-Heusler compounds, aiming to discover new semiconducting and half-metallic materials with tunable electronic properties for advanced applications.

Contribution

It systematically investigates 18-electron hexagonal compounds as potential semiconductors, proposing them as analogues to known zinc blende half-Heusler structures for novel magnetic and electronic functionalities.

Findings

Identification of potential hexagonal semiconductors with gaps in one spin channel

Proposal of new material families for half-metallicity through ion substitution

Potential applications in magnetoresistive and thermoelectric devices

Abstract

The XYZ half-Heusler crystal structure can conveniently be described as a tetrahedral zinc blende YZ structure which is stuffed by a slightly ionic X species. This description is well suited to understand the electronic structure of semiconducting 8-electron compounds such as LiAlSi (formulated Li$^+$[AlSi]$^-$) or semiconducting 18-electron compounds such as TiCoSb (formulated Ti$^{4+}$[CoSb]$^{4-}$). The basis for this is that [AlSi]$^-$ (with the same electron count as Si$_2$) and [CoSb]$^{4-}$ (the same electron count as GaSb), are both structurally and electronically, zinc-blende semiconductors. The electronic structure of half-metallic ferromagnets in this structure type can then be described as semiconductors with stuffing magnetic ions which have a local moment: For example, 22 electron MnNiSb can be written Mn$^{3+}$[NiSb]$^{3-}$. The tendency in the 18 electron compound for a semiconducting gap -- believed to arise from strong covalency -- is carried over in MnNiSb to a tendency for a gap in one spin direction. Here we similarly propose the systematic examination of 18-electron hexagonal compounds for semiconducting gaps; these would be the "stuffed wurtzite" analogues of the "stuffed zinc blende" half-Heusler compounds. These semiconductors could then serve as the basis for possibly new families of half-metallic compounds, attained through appropriate replacement of non-magnetic ions by magnetic ones. These semiconductors and semimetals with tunable charge carrier concentrations could also be interesting in the context of magnetoresistive and thermoelectric materials.