Two-fluid model analysis of the terahertz conductivity of YBaCuO samples: optimally doped, underdoped and overdoped cases

Abstract

The complex conductivity of underdoped and optimally doped YBa2Cu3O7-δ samples and overdoped similar compound Y0.7Ca0.3Ba2Cu3O7-δ was measured using time-domain terahertz spectroscopy. In the normal state, the frequency dependence is described by the Drude model. Below the critical temperature Tc, the two-fluid model was successfully employed to fit all the spectra, from 5 K up to Tc. The temperature behaviour of fundamental parameters such as the scattering rate 1/τ, the superfluid (normal) fraction fs (fn) and the conductivity σ was investigated at given frequencies. For the optimally doped and the overdoped samples, even at 5 K, a fifth of the electrons do not condense to the superfluid fraction. We observed that a substantial fraction of electrons do not condense to the superfluid fraction even at 5 K for optimally doped and overdoped samples. The real part of the conductivity σ1(T) exhibits a peak at low frequencies. It can be observed for all three stoichiometries and its exact shape depends on the quality of the sample. A further analysis shows that this peak is a consequence of the competition between the scattering time τ(T) and the superfluid fraction fs(T).