Understanding and prediction of electronic-structure-driven physical behaviors in rare-earth compounds

Rare-earth materials, due to their unique magnetic properties, are important for fundamental and technological applications such as advanced magnetic sensors, magnetic data storage, magnetic cooling and permanent magnets. For an understanding of the physical behaviors of these materials, first princ...

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Bibliographic Details
Published in:Journal of physics. Condensed matter 2013-10, Vol.25 (39), p.396002-396002
Main Authors: Paudyal, Durga, Pathak, Arjun K, Pecharsky, V K, Gschneidner Jr, K A
Format: Article
Language:English
Subjects:
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Correlation
Crystals
Electron density of states and band structure of crystalline solids
Electron states
Exact sciences and technology
Exchange
Exchange and superexchange interactions
Lanthanides
Magnetic properties
Magnetic properties and materials
Magnetically ordered materials: other intrinsic properties
Mathematical models
Permanent magnets
Physics
Rare earth metals
Rare earth metals and alloys
Splitting
Studies of specific magnetic materials
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Summary:Rare-earth materials, due to their unique magnetic properties, are important for fundamental and technological applications such as advanced magnetic sensors, magnetic data storage, magnetic cooling and permanent magnets. For an understanding of the physical behaviors of these materials, first principles techniques are one of the best theoretical tools to explore the electronic structure and evaluate exchange interactions. However, first principles calculations of the crystal field splitting due to intra-site electron-electron correlations and the crystal environment in the presence of exchange splitting in rare-earth materials are rarely carried out despite the importance of these effects. Here we consider rare-earth dialuminides as model systems and show that the low temperature anomalies observed in these systems are due to the variation of both exchange and crystal field splitting leading to anomalous intra-site correlated-4f and itinerant-5d electronic states near the Fermi level. From calculations supported by experiments we uncover that HoAl2 is unique among rare-earth dialuminides, in that it undergoes a cubic to orthorhombic distortion leading to a spin reorientation. Calculations of a much more extended family of mixed rare-earth dialuminides reveal an additional degree of complexity: the effective quadrupolar moment of the lanthanides changes sign as a function of lanthanide concentration, leading to a change in the sign of the anisotropy constant. At this point the quadrupolar interactions are effectively reduced to zero, giving rise to lattice instability and leading to new phenomena. This study shows a clear picture that accurate evaluation of the exchange, crystal field splitting and shape of the charge densities allows one to understand, predict and control the physical behaviors of rare-earth materials.
ISSN:0953-8984
1361-648X
DOI:10.1088/0953-8984/25/39/396002