Valence transition model of the pseudogap, charge order, and superconductivity in electron-doped and hole-doped copper oxides

Mazumdar, S.

doi:10.1103/physrevb.98.205153

Cited by 18 publications

(10 citation statements)

References 270 publications

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“…The local structure around one hole need not be compatible with the one around another, creating a large amount of small patches, or short-range HTT/LTT/LTO disorder, which can rearrange themselves with external fields and temperature changes. It has also been proposed that they order as a Wigner crystal, which contains pre-formed zero-coupled pairs [91]. Others have identified pre-formed pairs with the corresponding bipolarons [16].…”

Section: The S-p and D-p Transport Channelsmentioning

confidence: 99%

High-T$$_c$$ Cuprates: a Story of Two Electronic Subsystems

Barišić

Sunko

2022

J Supercond Nov Magn

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A review of the phenomenology and microscopy of cuprate superconductors is presented, with particular attention to universal conductance features, which reveal the existence of two electronic subsystems. The overall electronic system consists of $$1+p$$ 1 + p charges, where p is the doping. At low dopings, exactly one hole is localized per planar copper–oxygen unit, while upon increasing doping and temperature, the hole is gradually delocalized and becomes itinerant. Remarkably, the itinerant holes exhibit identical Fermi liquid character across the cuprate phase diagram. This universality enables a simple count of carrier density and yields comprehensive understanding of the key features in the normal and superconducting state. A possible superconducting mechanism is presented, compatible with the key experimental facts. The base of this mechanism is the interaction of fast Fermi liquid carriers with localized holes. A change in the microscopic nature of chemical bonding in the copper oxide planes, from ionic to covalent, is invoked to explain the phase diagram of these fascinating compounds.

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Section: The S-p and D-p Transport Channelsmentioning

confidence: 99%

High-T$$_c$$ Cuprates: a Story of Two Electronic Subsystems

Barišić

Sunko

2022

J Supercond Nov Magn

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“…The PEC is often adjacent to SC in the organic charge-transfer solids (CTS), which are all ρ = 0.5 materials [18]. Besides the CTS many other ρ = 0.5 superconductors are known [18], and this mechanism of SC has been further generalized to the cuprates [23]. E-p interactions are required to realize the PEC because of the bond distortion that simultaneously occurs with n.n.…”

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confidence: 99%

Superconductivity due to cooperation of electron-electron and electron-phonon interactions at quarter filling

Clay

Roy

2020

Phys. Rev. Research

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We present the results of Quantum Monte Carlo calculations for a two dimensional frustrated Hubbard model coupled to bond phonons. The model is known to have a d-wave superconducting ground state in the limit of large phonon frequency for sufficiently strong electron-phonon coupling. In the absence of electron-phonon coupling the Hubbard interaction U enhances superconducting pairing in the quarter-filled (density ρ = 0.5) band. We show here that at ρ = 0.5 electron-electron and electron-phonon interactions cooperatively reinforce d-wave pairing, while competing with each other at all other densities. Cooperative degrees of freedom are found in many phase transitions and are essential to understanding superconductivity in strongly correlated materials.

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“…The exceptionally large effort involved, both experimentally and theoretically, without a resolution over thirty years, naturally raises questions about the effort itself. Several recent synthetic works [3,4,5] indicate that mainstream theoretical approaches may have adopted a reductionist attitude too soon. In particular, the much-emphasized strong electronic correlations in the cuprates were dominantly studied in the minimal two-dimensional, one-band model of intraelectronic copper-site repulsion [6].…”

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

High-Temperature Superconductors as Ionic Metals

Sunko

2019

J Supercond Nov Magn

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High-temperature superconductors are reviewed in light of the fact that their binding energy is ionic. The conducting electrons are dominated by the much larger energy scales coming from ligand Coulomb integrals, including the out-of-plane ones, which are responsible for the Fermi arcs. The historic reinterpretation of Hund's rule from an intraelectronic to a central mean-field effect is applied to compare the cuprates to the pnictides. It is argued that the cuprates conform to the now-standard central-field paradigm, while the generally abandoned intraelectronic mechanism is exceptionally applicable to the pnictides. A non-adiabatic Fermi liquid paradigm is inferred from the phenomenological evidence. Glueless superconductivity is interpreted as the limiting case of Cooper-pair scattering in cuprates when the Cu ion is perfectly rigid.Keywords High-temperature superconductivity · Strong correlations · Fermi liquid 1 IntroductionNo generally accepted explanation exists for the superconductivity (SC) of cuprate perovskites [1] and ferropnictides [2]. The exceptionally large effort involved, both experimentally and theoretically, without a resolution over thirty years, naturally raises questions about the effort itself. Several recent synthetic works [3,4,5] indicate that mainstream theoretical approaches may have adopted a reductionist attitude too soon.

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Valence transition model of the pseudogap, charge order, and superconductivity in electron-doped and hole-doped copper oxides

Cited by 18 publications

References 270 publications

High-T$$_c$$ Cuprates: a Story of Two Electronic Subsystems

High-T$$_c$$ Cuprates: a Story of Two Electronic Subsystems

Superconductivity due to cooperation of electron-electron and electron-phonon interactions at quarter filling

High-Temperature Superconductors as Ionic Metals

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