Your search keyword '"J. Hänisch"' showing total 2 results

1. Quadrupling the depairing current density in the iron-based superconductor SmFeAsO 1-x H x .

Author

Miura M, Eley S, Iida K, Hanzawa K, Matsumoto J, Hiramatsu H, Ogimoto Y, Suzuki T, Kobayashi T, Ozaki T, Kurokawa H, Sekiya N, Yoshida R, Kato T, Okada T, Okazaki H, Yamaki T, Hänisch J, Awaji S, Maeda A, Maiorov B, and Hosono H

Abstract

Iron-based 1111-type superconductors display high critical temperatures and relatively high critical current densities J c . The typical approach to increasing J c is to introduce defects to control dissipative vortex motion. However, when optimized, this approach is theoretically predicted to be limited to achieving a maximum J c of only ∼30% of the depairing current density J d , which depends on the coherence length and the penetration depth. Here we dramatically boost J c in SmFeAsO 1-x H x films using a thermodynamic approach aimed at increasing J d and incorporating vortex pinning centres. Specifically, we reduce the penetration depth, coherence length and critical field anisotropy by increasing the carrier density through high electron doping using H substitution. Remarkably, the quadrupled J d reaches 415 MA cm -2 , a value comparable to cuprates. Finally, by introducing defects using proton irradiation, we obtain high J c values in fields up to 25 T. We apply this method to other iron-based superconductors and achieve a similar enhancement of current densities., (© 2024. The Author(s).)

Published

2024

2. Strain induced superconductivity in the parent compound BaFe2As2.

Author

Engelmann J, Grinenko V, Chekhonin P, Skrotzki W, Efremov DV, Oswald S, Iida K, Hühne R, Hänisch J, Hoffmann M, Kurth F, Schultz L, and Holzapfel B

Abstract

The discovery of superconductivity with a transition temperature, Tc, up to 65 K in single-layer FeSe (bulk Tc=8 K) films grown on SrTiO3 substrates has attracted special attention to Fe-based thin films. The high Tc is a consequence of the combined effect of electron transfer from the oxygen-vacant substrate to the FeSe thin film and lattice tensile strain. Here we demonstrate the realization of superconductivity in the parent compound BaFe2As2 (no bulk Tc) just by tensile lattice strain without charge doping. We investigate the interplay between strain and superconductivity in epitaxial BaFe2As2 thin films on Fe-buffered MgAl2O4 single crystalline substrates. The strong interfacial bonding between Fe and the FeAs sublattice increases the Fe-Fe distance due to the lattice misfit, which leads to a suppression of the antiferromagnetic spin density wave and induces superconductivity with bulk Tc≈10 K. These results highlight the role of structural changes in controlling the phase diagram of Fe-based superconductors.

Published

2013