Masanori Kohno scite author profile

The search for elementary excitations with fractional quantum numbers is a central challenge in modern condensed matter physics. We explore the possibility in a realistic model for several materials, the spin-1/2 spatially anisotropic frustrated Heisenberg antiferromagnet in two dimensions. By restricting the Hilbert space to that expressed by exact eigenstates of the Heisenberg chain, we derive an effective Schrödinger equation valid in the weak interchain-coupling regime. The dynamical spin correlations from this approach agree quantitatively with inelastic neutron measurements on the triangular antiferromagnet Cs2CuCl4. The spectral features in such antiferromagnets can be attributed to two types of excitations: descendents of one-dimensional spinons of individual chains, and coherently propagating "triplon" bound states of spinon pairs. We argue that triplons are generic features of spatially anisotropic frustrated antiferromagnets, and arise because the bound spinon pair lowers its kinetic energy by propagating between chains. PACS numbers:

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Mott Transition in the Two-Dimensional Hubbard Model

Kohno

2012

Phys. Rev. Lett.

200

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Spectral properties of the two-dimensional Hubbard model near the Mott transition are investigated by using cluster perturbation theory. The Mott transition is characterized by freezing of the charge degrees of freedom in a single-particle excitation that leads continuously to the magnetic excitation of the Mott insulator. Various anomalous spectral features observed in cuprate high-temperature superconductors are explained in a unified manner as properties near the Mott transition.

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Spectral Properties near the Mott Transition in the One-Dimensional Hubbard Model

Kohno

2010

Phys. Rev. Lett.

123

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The single-particle spectral properties near the Mott transition in the one-dimensional Hubbard model are investigated by using the dynamical density-matrix renormalization group method and the Bethe ansatz. The pseudogap, hole-pocket behavior, spectral-weight transfer, and upper Hubbard band are explained in terms of spinons, holons, antiholons, and doublons. The Mott transition is characterized by the emergence of a gapless mode whose dispersion relation extends up to the order of hopping t (spin exchange J) in the weak (strong) interaction regime caused by infinitesimal doping.

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Physics in Fermi level pinning at the polySi/Hf-based high-k oxide interface

Shiraishi

Yamada

Torii

et al. 2004

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Masanori Kohno

Spinons and triplons in spatially anisotropic frustrated antiferromagnets

Mott Transition in the Two-Dimensional Hubbard Model

Spectral Properties near the Mott Transition in the One-Dimensional Hubbard Model

Physics in Fermi level pinning at the polySi/Hf-based high-k oxide interface

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