Using the structural data of the La2CuO4 compound both in the distorted low-temperature tetragonal phase and in the isotropic phase, we have derived an effective t-J model with hoppings t and superexchange interactions J extended up to the fourth- and second-nearest-neighbors, respectively. By numerically studying this Hamiltonian we have then reproduced the main experimental features of this high-temperature superconductivity compound: d-wave superconductivity is stabilized at small but finite doping deltagreater than or similar to6% away from the antiferromagnetic region and some evidence of dynamical stripes is found at commensurate filling 1/8.
First principles electronic model for high-temperature superconductivity / Anisimov, Vi; Korotin, Ma; Nekrasov, Ia; Pchelkina, Zv; Sorella, Sandro. - In: PHYSICAL REVIEW. B, CONDENSED MATTER AND MATERIALS PHYSICS. - ISSN 1098-0121. - 66:10(2002), pp. 1-4. [10.1103/PhysRevB.66.100502]
First principles electronic model for high-temperature superconductivity
Sorella, Sandro
2002-01-01
Abstract
Using the structural data of the La2CuO4 compound both in the distorted low-temperature tetragonal phase and in the isotropic phase, we have derived an effective t-J model with hoppings t and superexchange interactions J extended up to the fourth- and second-nearest-neighbors, respectively. By numerically studying this Hamiltonian we have then reproduced the main experimental features of this high-temperature superconductivity compound: d-wave superconductivity is stabilized at small but finite doping deltagreater than or similar to6% away from the antiferromagnetic region and some evidence of dynamical stripes is found at commensurate filling 1/8.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.