Anisotropy of the irreversibility field for Zr-doped (Y,Gd)Ba2Cu3O7-x thin films up to 45T

Abstract

The anisotropic irreversibility field BIrr of two YBa2Cu3O7-x thin films doped with additional rare earth (RE)=(Gd,Y) and Zr and containing strong correlated pins (splayed BaZrO3 nanorods, and RE2O3 nanoprecipitates), has been measured over a very broad range up to 45T at temperatures 56 K<T<Tc. We found that the experimental angular dependence of BIrr(θ) does not follow the mass anisotropy scaling BIrr(θ)=BIrr(0)(cos2θ+γ-2sin2θ)-1/2, where γ=(mc/mab)1/2=5-6 for the RE-doped YBa2Cu3O7-x (REBCO) crystals, mab and mc are the effective masses along the ab plane and the c-axis, respectively, and θ is the angle between B and the c-axis. For B parallel to the ab-planes and to the c-axis correlated pinning strongly enhances BIrr, while at intermediate angles, BIrr(θ) follows the scaling behavior BIrr(θ)(cos2θ+γRP2sin2θ)1/2 with the effective anisotropy factor γRP≈3 significantly smaller than the mass anisotropy would suggest. In spite of the strong effects of c-axis BaZrO3 nanorods, we found even greater enhancements of BIrr for fields along the ab-planes than for fields parallel to the c-axis, as well as different temperature dependences of the correlated pinning contributions to BIrr for B//ab and B//c. Our results show that the dense and strong pins, which can now be incorporated into REBCO thin films in a controlled way, exert major and diverse effects on the measured vortex pinning anisotropy and the irreversibility field over wide ranges of B and T. In particular, we show that the relative contribution of correlated pinning to BIrr for B//c increases as the temperature increases due to the suppression of thermal fluctuations of vortices by splayed distribution of BaZrO3 nanorods.