Takashi Yanagisawa^1*, Mitake Miyazaki², Kunihiko Yamaji^1
1Electronics and Photonics Research Institute, National Institute of Advanced Industrial Science and Technology, 1-1-1 Umezono, Tsukuba, Japan.
²Hakodate National College of Technology, 14-1 Tokura, Hakodate, Japan.
DOI: 10.4236/jamp.2014.25010   PDF    HTML     3,461 Downloads   4,475 Views   Citations

Abstract

Electron correlation plays a key role in high-temperature cuprate superconductors. Material-parameter dependence of cuprates is important to clarify the mechanism of high temperature superconductivity. In this study, we examine the ground state of the three-band Hubbard model (d-p model) that explicitly includes oxygen p orbitals. We consider the half-filled case with the large
on-site Coulomb repulsion Ud by using the variational Monte Carlo method. The ground state is insulating when Ud is large at half-filling. The ground state undergoes a transition from a metal to a Mott insulator when the level difference εp-εd is increased.

Keywords

High-Temperature Superconductor, Electron Correlation, Mott Insulator, Metal-Insulator Transition, Charge-Transfer Insulator

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Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	Bennemann, K.H. and Ketterson, J.B. (2003) The Physics of Superconductors Vol. 1 and Vol. II. Springer-Verlag, Berlin.
[2]	Hirsch, J.E., Loh, D., Scalapio, D.J. and Tang, S. (1989) Physical Review, B39, 243.
[3]	Scalettar, R.T., Scalapino, D.J., Sugar, R.L. and White, S.R. (1989) Physical Review, B39, 243.
[4]	Guerrero, M., Gubernatis, J.E. and Zhang, S. (1998) Physical Review, B57, 11980.
[5]	Koikegami, S. and Yamada, K. (2000) Journal of the Physical Society of Japan, 69, 768.
[6]	Yanagisawa, T., Koike, S. and Yamaji, K. (2001) Physical Review, B64, 184509.
[7]	Yanagisawa, T., Koike, S. and Yamaji, K. (2003) Physical Review, B67, 132408.
[8]	Weber, C., Lauchi, A., Mila, F. and Giamarchi, T. (2009) Physical Review Letters, 102, 017005.
[9]	Yanagisawa, T., Miyazaki, M. and Yamaji, K. (2009) Journal of the Physical Society of Japan, 78, 013706.
[10]	Lau, B., Berciu, M. and Sawatzky, G.A. (2011) Physical Review Letters, 106, 036401.
[11]	Yanagisawa, T., Koike, S. and Yamaji, K.( 1998) Journal of the Physical Society of Japan, 67, 3867.
[12]	Koike, S., Yamaji, K. and Yanagisawa, T. (1999) Journal of the Physical Society of Japan, 68, 1657.
[13]	Yamaji, K., Yanagisawa, T. and Koike, S. (2000) Physica, B284-288, 415.
[14]	Yamaji, K., Shimoi, Y. and Yanagisawa, T. (1994) Physica, C235-240, 2221.
[15]	Miyazaki, M., Yanagisawa, T. and Yamaji, K. (2004) Journal of the Physical Society of Japan, 73, 1643.
[16]	Miyazaki, M., Yamaji, K., Yanagisawa, T. and Kadono, R. (2009) Journal of the Physical Society of Japan, 78, 043706.
[17]	Yamaji, K. and Yanagisawa, T. (2010) Journal of the Physical Society of Japan, 80, 083702.
[18]	Hybertsen, M.S., Schluter, M. and Christensen, N.E. (1989) Physical Review, B39, 9028.
[19]	Eskes, H., Sawatzky, G.A. and Feiner, L.F. (1989) Physica, C160, 424.
[20]	McMahan, A.K., Annett, J.F. and Martin, R.M. (1990) Physical Review, B42, 6268.
[21]	Eskes, H. and Sawatzky, G.A. (1991) Physical Review, B43, 119.
[22]	Hirsch, J.E., Scalapino, D.J. and Sugar, R.L. (1981) Physical Review Letters, 47, 1628.
[23]	Yanagisawa, T. (2007) Physical Review, B75, 224503.
[24]	Yanagisawa, T. (2013) New Journal of Physics, 15, 033012.
[25]	Yokoyama, H., Ogata, M. and Tanaka, Y. (2006) Journal of the Physical Society of Japan, 75, 114706.
[26]	Zaanen, J., Sawatzky, G.A. and Allen, J.W. (1985) Physical Review Letters, 55, 418.
[27]	Blawid, S., Tuan, H.A., Yanagisawa, T. and Fulde, P. (1996) Physical Review, B54, 7771.
[28]	Hubbard, J. (1963) Proceedings of the Royal Society, A276, 237.