Temperature dependence of magnetic-field angle dependent critical current density and the flux pinning in YBa₂Cu₃O₇ thin films

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• 作者：H. Yamasaki ; ^{h.yamasaki@aist.go.jp} ; I. Yamaguchi ; M. Sohma ; W. Kondo ; H. Matsui ; T. Manabe ; T. Kumagai
• 关键词：Critical current density ; Flux pinning ; YBCO film ; Random pinning ; Nano-precipitates ; Dislocations
• 刊名：Physica C
• 出版年：2012
• 期刊代码：80_09214534
• 类别：ms
• 出版时间：August, 2012
• 卷：478
• 期：Complete
• 页码：19-28
• 文件大小：1199 K

摘要

The magnetic-field angle dependence of the critical current density J_c(H, 胃) was measured over a wide temperature range (20-85 K) in high-J_c YBa₂Cu₃O₇ (YBCO) and DyBa₂Cu₃O₇ (DyBCO) epitaxial films belonging to two categories. The films in the first category were prepared by thermal co-evaporation and were characterized by a high density of nanometer-sized precipitates (mostly < 7 nm), which act as small random (point) pins. The films in the second category were prepared by fluorine-free metalorganic deposition (FF-MOD), whose primary pinning centers were recently revealed to be dislocations (linear pins) associated with stacking faults parallel to the ab-plane. Relatively broad J_c(胃) peaks around H//ab in the shape of a stratovolcano were observed at 77-80 K in the co-evaporated YBCO and DyBCO films in the first category, and the J_c(H, 胃) data were scaled to be a single curve when plotted against scaled fields using an effective anisotropy parameter. However, the J_c(胃) curves became more gradual at 60-70 K and the scaling behavior was broken because the radius of nano-precipitates was not sufficiently smaller than the temperature dependent Ginzburg-Landau coherence length 尉(T) at these temperatures. In contrast, sharp J_c(胃) peaks around H//ab were observed in the FF-MOD YBCO films in the second category at all temperatures in the range 20-85 K. Anisotropic scaling analysis showed that the pinning was apparently due to small random pins and pins correlated with the ab-plane, and the linear pins whose radius is sufficiently smaller than 尉(T) can cause the observed J_c(H, 胃). The temperature dependence of J_c due mainly to the random pinning was approximately 鈭?1 鈭?#xA0;T/T_c)²(1 + T/T_c)² for the FF-MOD thin films (dislocation pins), which is consistent with a simple theoretical model based on core pinning interactions. The T dependence of J_c for the co-evaporated films (nano-precipitate pins) was 鈭?1 鈭?#xA0;T/T_c)^m (1 + T/T_c)² (m = 2.1-2.6), which deviates from m = 2.5 expected from the simple theoretical model because nano-precipitates are not sufficiently smaller than 尉(T) at T 猢?#xA0;70 K.