Nonlinear Conduction by Melting of Stripe-Type Charge Order in Organic
  Conductors with Triangular Lattices

Chiba R.; Grüner G.; Inada T. S.; Ito T.; Kaneko M.; Kuroki K.; Miyagawa K.; Miyashita S.; Mori H.; Mori T.; Mori T.; Mori T.; Nogami Y.; Nogami Y.; Oka T.; Sawano F.; Seo H.; Suko T.; Taguchi Y.; Tajima H.; Tanaka Y.; Tanaka Y.; Tanaka Y.; Udagawa M.; Watanabe M.; Watanabe M.; Yamamoto K.; Yamanouchi S.; Yonemitsu K.

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Nonlinear Conduction by Melting of Stripe-Type Charge Order in Organic Conductors with Triangular Lattices

Authors: Chiba R.
Grüner G.
Inada T. S.
Ito T.
Kaneko M.
Kuroki K.
Miyagawa K.
Miyashita S.
Mori H.
Mori T.
Mori T.
Mori T.
Nogami Y.
Nogami Y.
Oka T.
Sawano F.
Seo H.
Suko T.
Taguchi Y.
Tajima H.
Tanaka Y.
Tanaka Y.
Tanaka Y.
Udagawa M.
Watanabe M.
Watanabe M.
Yamamoto K.
Yamanouchi S.
Yonemitsu K.
Publication date: 30 August 2011
Publisher: 'Japan Society of Applied Physics'
Doi

Abstract

We theoretically discuss the mechanism for the peculiar nonlinear conduction in quasi-two-dimensional organic conductors \theta-(BEDT-TTF)2X [BEDT-TTF=bis(ethylenedithio)tetrathiafulvalene] through the melting of stripe-type charge order. An extended Peierls-Hubbard model attached to metallic electrodes is investigated by a nonequilibrium Green's function technique. A novel current-voltage characteristic appears in a coexistent state of stripe-type and nonstripe 3-fold charge orders, where the applied bias melts mainly the stripe-type charge order through the reduction of lattice distortion, whereas the 3-fold charge order survives. These contrastive responses of the two different charge orders are consistent with the experimental observations.Comment: 5 pages, 4 figures, to appear in J. Phys. Soc. Jp

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