English

High-Temperature Superconductors Explained by Pairing in Spin-Density Waves

Superconductivity 2013-10-17 v1

Abstract

The spin-density wave (SDW) can be considered as a pair of charge density waves (CDWs), one composed only of electrons with up-spins and the other only of electrons with down-spins. The high-temperature superconductivity found in cuprates and pnictides may then be ascribed to BCS-type pairing between these SDWs, which is then no longer simple Cooper pairing between independent singlet electrons but rather involves collective interaction between Cooper pairs. The pseudo-gap may also be understood to originate from this BCS-type gap of the CDW system, in which the parameters are identical to those in the original BCS scheme, except that the electron-electron interaction is multiplied by a factor NCDW, which represents the number of electrons of the same spin direction that belong to a single CDW branch that comprises half the SDW. The superconducting gap then becomes an s dx2-y2-type gap. This gap may be calculated by assuming a modified BCS-like scheme that takes into account the contributions of the CDWs. These CDWs may be driven spatially into a checkerboard-shaped (or striped) form of superconductivity, depending on whether the CDW is two- or one-dimensional. The origin of the nodal gap may also be ascribed to the CDWs.

Keywords

Cite

@article{arxiv.1310.4273,
  title  = {High-Temperature Superconductors Explained by Pairing in Spin-Density Waves},
  author = {Je Huan Koo and Kwang Chul Son},
  journal= {arXiv preprint arXiv:1310.4273},
  year   = {2013}
}

Comments

14 pages, 5 figures

R2 v1 2026-06-22T01:47:56.084Z