Influence of carbon-ion irradiation on the superconducting critical properties of MgB2 thin films

Abstract

We investigate the influence of carbon-ion irradiation on the superconducting critical properties of MgB2 thin films. MgB2 films of two thicknesses viz. 400 nm (MB400nm) and 800 nm (MB800nm) were irradiated by 350 keV C ions having a wide range of fluence, 1 x 1013 - 1 x 1015 C atoms/cm2. The mean projected range (Rp) of 350 keV C ions in MgB2 is 560 nm, thus the energetic C ions will pass through the MB400nm, whereas the ions will remain into the MB800nm. The superconducting transition temperature (Tc), upper critical field (Hc2), c-axis lattice parameter, and corrected residual resistivity (corr) of both the films showed similar trends with the variation of fluence. However, a disparate behavior in the superconducting phase transition was observed in the MB800nm when the fluence was larger than 1 x 1014 C atoms/cm2 because of the different Tcs between the irradiated and non-irradiated parts of the film. Interestingly, the superconducting critical properties, such as Tc, Hc2, and Jc, of the irradiated MgB2 films, as well as the lattice parameter, were almost restored to those in the pristine state after a thermal annealing procedure. These results demonstrate that the atomic lattice distortion induced by C-ion irradiation is the main reason for the change in the superconducting properties of MgB2 films.