NMR and Neutron Scattering Experiments on the Cuprate Superconductors: A Critical Re-Examination
Abstract
We show that it is possible to reconcile NMR and neutron scattering experiments on both LSCO and YBCO, by making use of the Millis-Monien-Pines mean field phenomenological expression for the dynamic spin-spin response function, and reexamining the standard Shastry-Mila-Rice hyperfine Hamiltonian for NMR experiments. The recent neutron scattering results of Aeppli et al on LSCO (x=14%) are shown to agree quantitatively with the NMR measurements of 63T1 and the magnetic scaling behavior proposed by Barzykin and Pines. The reconciliation of the 17T1 relaxation rates with the degree of incommensuration in the spin fluctuation spectrum seen in neutron experiments is achieved by introducing a new transferred hyperfine coupling C' between oxygen nuclei and their next nearest neighbor Cu2+ spins; this leads to a near-perfect cancellation of the influence of the incommensurate spin fluctuation peaks on the oxygen relaxation rates of LSCO. The inclusion of the new C' term also leads to a natural explanation, within the one-component model, the different temperature dependence of the anisotropic oxygen relaxation rates for different field orientations, recently observed by Martindale et~al. The measured significant decrease with doping of the anisotropy ratio, R= 63T1ab/63T1c in LSCO system, from R =3.9 for La2CuO4 to R ~ 3.0 for LSCO (x=15%) is made compatible with the doping dependence of the shift in the incommensurate spin fluctuation peaks measured in neutron experiments, by suitable choices of the direct and transferred hyperfine coupling constants Aβ and B.
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