Pairing, Charge, and Spin Correlations in the Three-Band Hubbard Model
Abstract
Using the Constrained Path Monte Carlo (CPMC) method, we simulated the two-dimensional, three-band Hubbard model to study pairing, charge, and spin correlations as a function of electron and hole doping and the Coulomb repulsion Vpd between charges on neighboring Cu and O lattice sites. As a function of distance, both the dx2 - y2-wave and extended s-wave pairing correlations decayed quickly. In the charge-transfer regime, increasing Vpd decreased the long-range part of the correlation functions in both channels, while in the mixed-valent regime, it increased the long-range part of the s-wave behavior but decreased that of the d-wave behavior. Still the d-wave behavior dominated. At a given doping, increasing Vpd increased the spin-spin correlations in the charge-transfer regime but decreased them in the mixed-valent regime. Also increasing Vpd suppressed the charge-charge correlations between neighboring Cu and O sites. Electron and hole doping away from half-filling was accompanied by a rapid suppression of anti-ferromagnetic correlations.
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