Enhancement in the critical current density of BaTiO <sub>3</sub> -doped YBCO films by low-energy (60 keV) proton irradiation
Daxing Huang, Hongwei Gu, Hongjing Shang, Taiguang Li, Bowei Xie, Qi Zou, Di Chen, Wei‐Kan Chu, Fazhu Ding
Abstract
Abstract Although YBa 2 Cu 3 O 72212δ (YBCO) is one of the most promising superconducting materials for power applications, the fabrication of low-cost coated conductors with the high in-field performance remains challenging. Here, we report an efficient mixed-pinning landscape for enhancing the in-field performance of BaTiO 3 (BTO)-doped YBCO films by low-energy (60 keV) proton irradiation. The smaller (2–4 nm), weaker but perhaps denser pinning sites have been successfully introduced by irradiation, which can form a mixed-pinning landscape with pre-doped BTO precipitates (5–15 nm), leading to the increased vortex pinning. In this case, the critical current density ( J c ) of YBCO films increases significantly, especially at low temperature and high magnetic field, and it increases three times near 6 T at 20 K when the irradiation dose is 1 × 10 15 proton cm −2 . Additionally, the c -axis length ( c -parameter) of YBCO increases with the increase of irradiation dose, which indicates the decreasing oxygen content due to the excessive irradiation, thereby the reduction in critical transition temperature ( T c ). Employing low irradiation energy is beneficial for protons to stop inside YBCO film and thereby induces higher density defects when applying low doses. This fabrication technique is a practicable post-production solution to improve the in-field performance of nanoparticle-doped YBCO films.