Peculiarities in the pseudogap behavior in optimally doped YBa2Cu3O7-δ single crystals under pressure up to 1GPa

Abstract

The influence of the hydrostatic pressure P up to 0.95 GPa on the excess conductivity and the pseudogap *(T) in optimally doped YBCO single crystals (Tc = 91.1K at ambient pressure) is investigated by electrical resistivity measurements. A pronounced enhancement of the pseudogap under pressure of dln*/dP= 0.32, which is only a factor of 1.12 smaller than in slightly doped single crystals, is revealed for the first time. This implies a somewhat more moderate increase of the coupling strength in optimally doped cuprates with increasing pressure. Simultaneously, the ratio 2*(Tc)/kBTc=5 at P=0 GPa, which is typical for high-temperature superconductors with strong coupling, increases by 16% with increasing pressure. At the same time, the pressure effect on Tc is minor: dTc/dP=+0.73 K/GPa, whereas dln/dP=-17% 1/GPa is comparable with that in lightly doped YBCO single crystals. This suggests that the mechanisms of the pressure effect on (T) and Tc are noticeably different. Independently of pressure, near Tc, the excess conductivity is well described by the Aslamazov-Larkin (3D-AL) and 2D Hikami-Larkin fluctuation theories, exhibiting a 3D-2D crossover with increasing temperature. However, the temperature interval Tc<T<T01, in which excess conductivity obeys the classical fluctuation theories, is exceptionally narrow (~1.16 K). Nevertheless, a peculiarity at the temperature T01, up to which the wave function phase stiffness in the superconductor is maintained, is clearly observed in the dependence *(T). Below T01 a fast growth of *(T) is revealed for the first time. It can be associated with a sudden increase of the superfluid density, ns, that is the density of fluctuating Cooper pairs (short-range phase correlations) forming in the sample when T approaches Tc.