Cadmium Arsenides: Structure, Synthesis of Bulk and Film Crystals, Magnetic and Electrical Properties (Review)

The Cd–As system is distinguished by metastable states; three compounds, namely, Cd 3 As 2 , CdAs 2 , and CdAs 4 , are formed in the system under normal pressures. The last-listed compound, CdAs 4 , is metastable and can be prepared, as a rule, together with other phases that stabilize it, e.g., wit...

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Bibliographic Details
Published in:Russian journal of inorganic chemistry 2021-12, Vol.66 (14), p.2005-2016
Main Authors: Ril’, A. I., Marenkin, S. F.
Format: Article
Language:English
Subjects:
Anisotropy
Arsenic
Arsenides
Birefringence
Brillouin zones
Broken symmetry
Cadmium
Chemistry
Chemistry and Materials Science
Conduction bands
Crystal defects
Crystal structure
Electrical properties
Electron mobility
Graphene
Inorganic Chemistry
Intermetallic compounds
Magnetic properties
Magnetoresistance
Magnetoresistivity
Metastable state
NMR
Nuclear magnetic resonance
Optical properties
Single crystals
Superconductivity
Synthesis and Properties of Inorganic Compounds
Thermodynamic properties
Thin films
Valence band
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Summary:The Cd–As system is distinguished by metastable states; three compounds, namely, Cd 3 As 2 , CdAs 2 , and CdAs 4 , are formed in the system under normal pressures. The last-listed compound, CdAs 4 , is metastable and can be prepared, as a rule, together with other phases that stabilize it, e.g., with isostructural CdP 4 . The focus of research is Cd 3 As 2 . This compound was first regarded as a narrow-gap semiconductor with an abnormally high electron mobility. More recently, Cd 3 As 2 has been rediscovered as a 3D topological semimetal, positioned as a bulk analogue of graphene that has a negative magnetoresistance (NMR) and superconductivity. The conduction band and valence band of cadmium arsenide have a linear dispersion law and touch each other in the 3D Brillouin zone to form Dirac points. Provided the time reversal and inverted symmetry, the Dirac points are doubly degenerate. Symmetry breaking leads to splitting of a Dirac point. A magnetic field transforms the Weyl semimetal, generating NMR and giving rise to superconducting properties. The second stable compound of the three listed, CdAs 2 , is a semiconductor with a moderate bandgap width, and is distinguished by a high anisotropy of optical, electrical, and thermoelectrical properties. This compound is interesting due to the high value of birefringence in the IR. The review analyzes the synthetic methods to prepare single crystals and thin films. Data are presented on thermodynamic properties, the effects of doping with donor and acceptor dopants, types of defects, and their relations to optical and electrical properties. Present-day studies are reviewed.
ISSN:0036-0236
1531-8613
DOI:10.1134/S0036023621140059