Dynamic Exponent oft-Jandt-J-WModel
- 15 June 1998
- journal article
- Published by Physical Society of Japan in Journal of the Physics Society Japan
- Vol. 67 (6) , 1864-1867
- https://doi.org/10.1143/jpsj.67.1864
Abstract
Drude weight of optical conductivity is calculated at zero temperature by exact diagonalization for the two-dimensional t-J model with the two-particle term, $W$. For the ordinary t-J model with $W$=0, the scaling of the Drude weight $D \propto \delta^2$ for small doping concentration $\delta$ is obtained, which indicates anomalous dynamic exponent $z$=4 of the Mott transition. When $W$ is switched on, the dynamic exponent recovers its conventional value $z$=2. This corresponds to an incoherent-to-coherent transition associated with the switching of the two-particle transfer.Comment: LaTeX, JPSJ-style, 4 pages, 5 eps files, to appear in J. Phys. Soc. Jpn. vol.67, No.6 (1998
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This publication has 13 references indexed in Scilit:
- Charge and spin structures of asuperconductor in the proximity of an antiferromagnetic Mott insulatorPhysical Review B, 1997
- Ground-state properties of the two-dimensional t-J modelPhysical Review B, 1997
- Recent progress in NMR studies on organic conductorsHyperfine Interactions, 1997
- Quantum Transition between an Antiferromagnetic Mott Insulator andSuperconductor in Two DimensionsPhysical Review Letters, 1996
- Insulator-Metal Transition in the One- and Two-Dimensional Hubbard ModelsPhysical Review Letters, 1996
- Metal-Insulator Transition of Correlated Systems and Origin of Unusual MetalJournal of the Physics Society Japan, 1995
- Correlated electrons in high-temperature superconductorsReviews of Modern Physics, 1994
- Two-Dimensional Hubbard Model –Metal Insulator Transition Studied by Monte Carlo Calculation–Journal of the Physics Society Japan, 1992
- Twisted boundary conditions and effective mass in Heisenberg-Ising and Hubbard ringsPhysical Review Letters, 1990
- Attractive Interaction and Pairing in Fermion Systems with Strong On-Site RepulsionPhysical Review Letters, 1985