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In condensed matter physics, the resonating valence bond theory (RVB) is a theoretical model that attempts to describe high-temperature superconductivity, and in particular the superconductivity in cuprate compounds. It was first proposed by an American physicist P. W. Anderson and Indian theoretical physicist Ganapathy Baskaran in 1987.[1][2] The theory states that in copper oxide lattices, electrons from neighboring copper atoms interact to form a valence bond, which locks them in place. However, with doping, these electrons can act as mobile Cooper pairs and are able to superconduct. Anderson observed in his 1987 paper that the origins of superconductivity in doped cuprates was in the Mott insulator nature of crystalline copper oxide.[3] RVB builds on the Hubbard and t-J models used in the study of strongly correlated materials.[4]

In 2014, evidence showing that fractional particles can happen in quasi two-dimensional magnetic materials, was found by EPFL scientists[5] lending support for Anderson's theory of high-temperature superconductivity.[6]

Description

The RVB state with valence bond coupling of nearest-neighbor electrons.

The physics of Mott insulators is described by the repulsive Hubbard model Hamiltonian:

In 1971, Anderson first suggested that this Hamiltonian can have a non-degenerate ground state that is composed of disordered spin states. Shortly after the high-temperature superconductors were discovered, Anderson and Kivelson et al. proposed a resonating valence bond ground state for these materials, written as

where represented a covering of a lattice by nearest neighbor dimers. Each such covering is weighted equally. In a mean field approximation, the RVB state can be written in terms of a Gutzwiller projection, and displays a superconducting phase transition per the Kosterlitz–Thouless mechanism.[7] However, a rigorous proof for the existence of a superconducting ground state in either the Hubbard or the t-J Hamiltonian is not yet known.[7] Further the stability of the RVB ground state has not yet been confirmed.[8]

References

  1. ^ Mann, Adam (2011). "High-temperature superconductivity at 25: Still in suspense". Nature. 475 (7356): 280–282. Bibcode:2011Natur.475..280M. doi:10.1038/475280a. PMID 21776057.
  2. ^ Cho, Adrian (30 March 2020). "Philip Anderson, legendary theorist whose ideas shaped modern physics, dies". Science. AAAS. doi:10.1126/science.abb9809. Retrieved 25 May 2020.
  3. ^ Zaanen, Jan (2010). "A modern, but way too short history of the theory of superconductivity at a high temperature". arXiv:1012.5461 [cond-mat.supr-con].
  4. ^ Weber, Cédric (2007). Variational Study of Strongly Correlated Electron Models (PDF). École Polytechnique Fédérale de Lausanne. Archived from the original (PDF) on 2018-10-01. Retrieved 2012-04-08.
  5. ^ Piazza, B. Dalla (2015). "Fractional excitations in the square-lattice quantum antiferromagnet". Nature Physics. 11 (1): 62–68. arXiv:1501.01767. Bibcode:2015NatPh..11...62D. doi:10.1038/nphys3172. PMC 4340518. PMID 25729400.
  6. ^ "How electrons split: New evidence of exotic behaviors". Nanowerk. École Polytechnique Fédérale de Lausanne. Dec 23, 2014. Retrieved Dec 23, 2014.
  7. ^ a b Baskaran, Ganapathy (2009). "Five-fold way to new high Tc superconductors" (PDF). Pramana. 73 (1): 61–112. Bibcode:2009Prama..73...61B. doi:10.1007/s12043-009-0094-8. S2CID 73670216. Retrieved 8 April 2012.
  8. ^ Dombre, Thierry; Gabriel Kotliar (1989). "Instability of the long-range resonating valence bond state in the mean-field approach" (PDF). Physical Review B. 39 (1): 855–857. Bibcode:1989PhRvB..39..855D. doi:10.1103/PhysRevB.39.855. PMID 9947250. Retrieved 8 April 2012.