Magnetic Properties of YBa2Cu3O7-δ in a self-consistent approach: Comparison with Quantum-Monte-Carlo Simulations and Experiments
Abstract
We analyze single-particle electronic and two-particle magnetic properties of the Hubbard model in the underdoped and optimally-doped regime of by means of a modified version of the fluctuation-exchange approximation, which only includes particle-hole fluctuations. Comparison of our results with Quantum-Monte Carlo (QMC) calculations at relatively high temperatures (T 1000 K) suggests to introduce a temperature renormalization in order to improve the agreement between the two methods at intermediate and large values of the interaction U. We evaluate the temperature dependence of the spin-lattice relaxation time T1 and of the spin-echo decay time T2G and compare it with the results of NMR measurements on an underdoped and an optimally doped sample. For U/t=4.5 it is possible to consistently adjust the parameters of the Hubbard model in order to have a good semi-quantitative description of this temperature dependence for temperatures larger than the spin gap as obtained from NMR measurements. We also discuss the case U/t 8, which is more appropriate to describe magnetic and single-particle properties close to half-filling. However, for this larger value of U/t the agreement with QMC as well as with experiments at finite doping is less satisfactory.
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