Mott physics and band topology in materials with strong spin–orbit interaction

Pesin, D. A.; Balents, Leon

doi:10.1038/nphys1606

Cited by 1,068 publications

(1,289 citation statements)

References 44 publications

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“…The trigonal crystal field then opens up an energy gap within each manifold, and a non-trivial Z 2 topology can be realized. This is similar to the results reported on Iridium compounds 17,18 . In the weak SOC limit, bands from j = 1/2 and j = 3/2 orbitals become mixed away from the Γ point.…”

Section: Resultssupporting

confidence: 92%

Interface engineering of quantum Hall effects in digital transition metal oxide heterostructures

et al. 2011

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Topological insulators are characterized by a non-trivial band topology driven by the spin-orbit coupling. To fully explore the fundamental science and application of topological insulators, material realization is indispensable. Here we predict, based on tight-binding modelling and first-principles calculations, that bilayers of perovskite-type transition-metal oxides grown along the [111] crystallographic axis are potential candidates for two-dimensional topological insulators. The topological band structure of these materials can be fine-tuned by changing dopant ions, substrates and external gate voltages. We predict that LaAuo 3 bilayers have a topologically non-trivial energy gap of about 0.15 eV, which is sufficiently large to realize the quantum spin Hall effect at room temperature. Intriguing phenomena, such as fractional quantum Hall effect, associated with the nearly flat topologically non-trivial bands found in e g systems are also discussed.

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Section: Resultssupporting

confidence: 92%

Interface engineering of quantum Hall effects in digital transition metal oxide heterostructures

et al. 2011

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“…Further fitting the data above 50 K to a modified Curie− Weiss (CW) law (8), which is in same direction but numerically different from the (g ⊥ /g ∥ ) 2 = 0.50 (5) in the plot of (M/H) ⊥ (T) versus (M/H) ∥ (T). This is because the latter assumes same functional form for (M/H) ⊥ (T) and (M/H) ∥ (T), which is not the case if θ is anisotropic.…”

Section: ■ Results and Discussionmentioning

confidence: 97%

Crystal Structure, Transport, and Magnetic Properties of an Ir⁶⁺ Compound Ba₈Al₂IrO₁₄

Yang¹,

Pisoni²,

Magrez³

et al. 2015

Inorg. Chem.

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ABSTRACT:The novel iridate Ba 8 Al 2 IrO 14 was prepared as single crystals by self-flux method, thereby providing a rare example of an all-Ir(VI) compound that can be synthesized under ambient pressure conditions. The preparation of all-Ir 6+ iridate without using traditional high-pressure techniques has to our knowledge previously only been reported in Nd 2 K 2 IrO 7 and Sm 2 K 2 IrO 7 . The monoclinic crystal structure (space group C2/m, No.12) is stable down to 90 K and contains layers of IrO 6 octahedra separated by Ba and AlO 4 tetrahedra. The material exhibits insulating behavior with a narrow band gap of ∼0.6 eV. The positive Seebeck coefficient indicates hole-like dominant charge carriers. Susceptibility measurement shows antiferromagnetic coupling with no order down to 2 K.

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“…For d = 0 this ratio is not a function of n. It should also be noted that, for short range scatterers, the ratio τ δ /τ Qδ is a constant as a function of n, which we find to be 1. 46.…”

Section: Numerical Resultsmentioning

confidence: 99%

“…44 Topological phases in transition-metal based strongly correlated systems have been the subject of Refs. 45,46, and a theory relating topological insulators to Mott physics has been proposed in Ref. 47.…”

Section: Introductionmentioning

confidence: 99%

Two-dimensional surface charge transport in topological insulators

et al. 2010

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We construct a theory of charge transport by the surface states of topological insulators in three dimensions. The focus is on the experimentally relevant case when the Fermi energy εF and transport scattering time τ satisfy εF τ / 1, but εF lies below the bottom of the conduction band. Our theory is based on the spin density matrix and takes the quantum Liouville equation as its starting point. The scattering term is determined to linear order in the impurity density ni and explicitly accounts for the absence of backscattering, while screening is included in the random phase approximation. The main contribution to the conductivity is ∝ n −1 i and has different carrier density dependencies for different forms of scattering, while an additional contribution is independent of ni. The dominant scattering angles can be inferred by studying the ratio of the transport time to the Bloch lifetime as a function of the Wigner-Seitz radius rs. The current generates a spin polarization that could provide a smoking-gun signature of surface state transport. We also discuss the effect on the surface states of adding metallic contacts.

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Mott physics and band topology in materials with strong spin–orbit interaction

Cited by 1,068 publications

References 44 publications

Interface engineering of quantum Hall effects in digital transition metal oxide heterostructures

Interface engineering of quantum Hall effects in digital transition metal oxide heterostructures

Crystal Structure, Transport, and Magnetic Properties of an Ir⁶⁺ Compound Ba₈Al₂IrO₁₄

Two-dimensional surface charge transport in topological insulators

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Mott physics and band topology in materials with strong spin–orbit interaction

Cited by 1,068 publications

References 44 publications

Interface engineering of quantum Hall effects in digital transition metal oxide heterostructures

Interface engineering of quantum Hall effects in digital transition metal oxide heterostructures

Crystal Structure, Transport, and Magnetic Properties of an Ir6+ Compound Ba8Al2IrO14

Two-dimensional surface charge transport in topological insulators

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Crystal Structure, Transport, and Magnetic Properties of an Ir⁶⁺ Compound Ba₈Al₂IrO₁₄