d-Wave superconductivity from correlated-hopping interactions determined by angle-resolved photoemission spectroscopy

Starting from a generalized Hubbard model with correlated-hopping interactions, we solve numerically two coupled integral equations within the Bardeen–Cooper–Schrieffer formalism, in order to study the doping effects on the critical temperature (Tc), d-wave superconducting gap, and the electronic specific heat. Within the mean-field approximation, we determine the single- and correlated-electron-hopping parameters for La2 − xSrxCuO4 by using angle-resolved photoemission spectroscopy data. The resulting parametrized Hubbard model is able to explain the experimental Tc variation with the doping level (x). Moreover, the observed power-law behavior of the superconducting specific heat is reproduced by this correlated-hopping Hubbard model without adjustable parameters. © 2012 Elsevier B.V.

ARPES; d-Wave superconductivity; Hubbard model Integral equations; Photoelectron spectroscopy; Specific heat; Superconducting materials; Adjustable parameters; Angle resolved photoemission spectroscopy; ARPES; Coupled integral equations; Critical temperatures; D-wave superconductivity; Electronic specific heat; Mean field approximation; Hubbard model

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