Search for mid- and high-entropy transition-metal chalcogenides - investigating the pentlandite structure

For the first time, transition metal-based chalcogenides conforming to the definition of high entropy materials, are synthesized, with the multicomponent occupation being utilized on both cationic and anionic sublattices. The pentlandite-structured (Co,Fe,Ni) 9 S 8 and (Co,Fe,Ni) 9 (S,Se) 8 composit...

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Published in:Dalton transactions : an international journal of inorganic chemistry 2021-07, Vol.5 (27), p.956-9573
Main Authors: Miku a, Andrzej, D browa, Juliusz, Kusior, Anna, Mars, Krzysztof, Lach, Rados aw, Kubowicz, Maciej
Format: Article
Language:English
Subjects:
Chalcogenides
Cobalt
Electrical resistivity
Entropy
Hydrazines
Hydrogen evolution reactions
Iron
Lattice parameters
Nickel ores
Optical measurement
Pentlandite
Photoelectrochemical devices
Room temperature
Seebeck effect
Structural analysis
Thermal conductivity
Transition metal compounds
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Summary:For the first time, transition metal-based chalcogenides conforming to the definition of high entropy materials, are synthesized, with the multicomponent occupation being utilized on both cationic and anionic sublattices. The pentlandite-structured (Co,Fe,Ni) 9 S 8 and (Co,Fe,Ni) 9 (S,Se) 8 compositions are obtained using a two-stage, solid-state reaction method. Room temperature structural analysis (XRD, SEM, Raman) in both cases indicates the presence of a homogeneous, single-phase, Fm 3&cmb.macr; m structure, with a profound effect of Se addition on the lattice parameters. The obtained materials possess an excellent electrical conductivity of 10 5 S m −1 , and slightly negative Seebeck coefficient values, resulting from their metallic character, combined with a low thermal conductivity of 2.5 W m −1 K −1 , especially when compared with conventional analogues. The optical measurements reveal very promising behavior in the UV/vis range. The electrochemical sensitivity towards hydrazine and acetaminophen is also presented, making them potentially interesting for sensor devices. Based on the DFT analysis of various sub-systems, the origins of the observed transport and optical behavior are explained. Furthermore, it is shown that the application of the high-entropy principle to both sublattices simultaneously allows for extensive tailoring of the band structure, allowing these materials to be optimized with respect to the given application, including thermoelectric and photoelectrochemical devices and catalysis, e.g. , the hydrogen evolution reaction. For the first time, the high entropy, transition metal-based chalcogenides are synthesized. The materials are characterized by the pentlandite structure, exhibiting promising functional properties with regard to multiple possible applications.
ISSN:1477-9226
1477-9234
DOI:10.1039/d1dt00794g