Formation Mechanism of Hybridization Gap in Kondo Insulators based on a Realistic Band Model and Application to YbB<sub>12</sub>

Saso, Tetsuro; Harima, Hisatomo

doi:10.1143/jpsj.72.1131

Cited by 46 publications

(41 citation statements)

References 39 publications

(49 reference statements)

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“…This scheme was performed in ref. 16 for YbB 12 and we follow the same procedure here. The resulting f bands, which will be shown in the next section, are rather similar to those above the Fermi level obtained by the LDA band calculation.…”

Section: Model and Formulationmentioning

confidence: 99%

Optical Conductivity of Ce-based Filled Skutterudites

Mutou

Saso

2004

J. Phys. Soc. Jpn.

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A simple tight-binding model is constructed for the description of the electronic structure of some Ce-based filled skutterudite compounds showing an energy gap or pseudogap behavior. Assuming band-diagonal electron interactions on this tight-binding model, the optical conductivity spectrum is calculated by applying the second-order self-consistent perturbation theory to treat the electron correlation. The correlation effect is found to be of great importance on the description of the temperature dependence of the optical conductivity. The rapid disappearance of an optical gap with increasing temperature is obtained as observed in the optical experiment for Ce-based filled-skutterudite compounds.

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Section: Model and Formulationmentioning

confidence: 99%

Optical Conductivity of Ce-based Filled Skutterudites

Mutou

Saso

2004

J. Phys. Soc. Jpn.

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“…20 Very recently, Weng et al have predicted that the simple cubic YbB 6 is a candidate topological insulator, while YbB 12 with a rock-salt structure is a potential candidate topological crystalline insulator with a nontrivial mirror Chern number protected by mirror symmetry. 21,22 Angle-resolved photoemission spectroscopy (ARPES) also suggested YbB 6 as a candidate TKI. 23 In fact, there are hundreds of rare-earth compounds RX with a rock-salt structure, with R referring to the rare-earth Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, and Lu, and X standing for the pnictide atoms N, P, As, Sb, Bi and the chalcogenide atoms O, S, Se, Te, Po.…”

Section: Introductionmentioning

confidence: 99%

Pressure-Driven Topological Phase Transition in the Yb Chalcogenides YbO and YbS

Zhang

2015

J. Phys. Soc. Jpn.

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“…4 The indirect gap is about 0.007 Ry (∼ 1100 K) between X and L points and the direct gap is 0.02 Ry (∼ 0.25 eV). The former is about six times larger than the best estimated value of the indirect gap in the optical experiment, E g =174 K. However, in the present realistic band model, we use the larger value mentioned above simply because of the technical reason in numerical calculation.…”

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“…Based on the LDA+U band calculation, we previously constructed a tight-binding band composed of the 5d and 4f Γ 8 orbitals both on Yb atoms, where B 12 orbitals were eliminated. 4 Some of the dconduction bands are doubly degenerate (four-fold if spin degeneracy is included). A gap opens by the hybridization with the four-fold degenerate Γ 8 states with the dconduction bands with degeneracy.…”

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Comparison of Semimetallic Ce-Skutterudites and the Kondo Insulator YbB₁₂–Field-Induced Insulator-to-Metal and Metal-to-Insulator Transitions

2008

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YbB12 is a typical Kondo insulator with an energy gap Eg ∼ 100K. It has a cubic symmetry, but the gap closing field shows anisotropy when magnetic field is applied. CeOs4Sb12 shows weak insulating behavior below 50T. It, however, should be a semimetal according to the rule that most Ce-skutterudite compounds with lattice constant larger than 8.5 Angstrom are semimetal, and a reason for the weak insulating behavior is still unknown. We construct aproapriate tight-binding band models for these compounds and investigate the magnetic field effects on them.KEYWORDS: Kondo insulator, YbB12, CeOs4Sb12, magnetization, magnetic field Magnetic field effects are of much interest in the study of heavy electron compounds since many of the physical properties are enhanced by the Kondo effect, which is very sensitive to the magnetic field. In this paper, we choose YbB 12 as a typical Kondo insulator, 1 which shows a magnetic-field-induced insulator-to-metal transition at about the field B =50T, 2 and the skutterudite compound CeOs 4 Sb 12 , which is a semimetal for T > 50K, but shows a weak insulating behabior below that temperature.3 A reason for the latter behavior is still unknown, but one possibility will be the Anderson localization due to a small number of carriers. Since there is an empirical rule that most Ce-skutterudite compounds with lattice constant larger than 8.5 Angstrom are semimetal, 3 we start from a semimetallic model for CeOs 4 Sb 12 , and investigate a magnetic field effect on this material.YbB 12 has a cubic crystal structure (Yb and B 12 forms NaCl structure). Based on the LDA+U band calculation, we previously constructed a tight-binding band composed of the 5d and 4f Γ 8 orbitals both on Yb atoms, where B 12 orbitals were eliminated.4 Some of the dconduction bands are doubly degenerate (four-fold if spin degeneracy is included). A gap opens by the hybridization with the four-fold degenerate Γ 8 states with the dconduction bands with degeneracy. It was pointed out that the gap can not open if the crystal-field groud state of 4f were Γ 7 doublet. Therefore, proper consideration of the degeneracy is a key to understanding the opening 4 and closing of a gap in the Kondo insulators.Based on this band model, one of the authors 5 calculated frequency-and temperature-dependence of the optical conductivity and obtained semi-quantitative agreement with the experiment.6 YbB 12 , however, still has many features to be understood correctly and quantitatively. One of them is the magnetic properties. Sugiyama, et al.2 found the field-induced insulator-to-metal transition at the critical field B c ∼ 50T. Iga, et al. der since hysterisis is observed. This first order transition was theoretically explained using the simple periodic Anderson model with the Coulomb repulsion. 9, 10 Here we investigate the origin and mechanism of the anisotropy of B c by using the more sophisticated model which takes account of the anisotropy of the 4f orbitals.The tight-binding Hamiltonian is generally written aswhere t αβ ij denotes the h...

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Formation Mechanism of Hybridization Gap in Kondo Insulators based on a Realistic Band Model and Application to YbB₁₂

Cited by 46 publications

References 39 publications

Optical Conductivity of Ce-based Filled Skutterudites

Optical Conductivity of Ce-based Filled Skutterudites

Pressure-Driven Topological Phase Transition in the Yb Chalcogenides YbO and YbS

Comparison of Semimetallic Ce-Skutterudites and the Kondo Insulator YbB₁₂–Field-Induced Insulator-to-Metal and Metal-to-Insulator Transitions

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Formation Mechanism of Hybridization Gap in Kondo Insulators based on a Realistic Band Model and Application to YbB12

Cited by 46 publications

References 39 publications

Optical Conductivity of Ce-based Filled Skutterudites

Optical Conductivity of Ce-based Filled Skutterudites

Pressure-Driven Topological Phase Transition in the Yb Chalcogenides YbO and YbS

Comparison of Semimetallic Ce-Skutterudites and the Kondo Insulator YbB12–Field-Induced Insulator-to-Metal and Metal-to-Insulator Transitions

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Formation Mechanism of Hybridization Gap in Kondo Insulators based on a Realistic Band Model and Application to YbB₁₂

Comparison of Semimetallic Ce-Skutterudites and the Kondo Insulator YbB₁₂–Field-Induced Insulator-to-Metal and Metal-to-Insulator Transitions