Abstract
Iron-based superconductors have strong potential for magnet applications through their very high upper critical field, low anisotropy and manufacturability through the powder-in-tube (PIT) route. The engineering critical current density (J(e)) is a key parameter for measuring the maximum current density that superconducting materials can withstand in practical applications. It serves as a bridge between theoretical research and practical applications of superconductors and has great significance in promoting the development and application of superconducting technology. In this study, Ag sheathed Ba(0.6)K(0.4)Fe(2)As(2) (Ba-122) iron-based superconducting tapes were prepared by using the process of drawing, flat rolling and heat treatment by hot pressing (HP). For the first time, the filling factor of the tapes increased to about 40%, leading to a reduction in the volume fraction of Ag, consequently lowering the overall cost. The optimal parameters for achieving high transport J(e) were obtained by comparing the effects of different HP pressures on the properties and micro-morphology of the tapes. The prepared mono-filament tapes are capable of carrying the transport J(e) of 4.1 × 10(4) A/cm(2) (I(c) = 350 A) at 4.2 K, 10 T, marking the highest J(e) reported for Ba-122 wires and tapes to date. Our results show that high transport J(e) can be obtained in Ba-122 superconducting tapes, and iron-based superconductors have a promising future in practical applications.