Pressure effects on the electronic properties of the undoped superconductor ThFeAsN

Abstract

The recently synthesized ThFeAsN iron-pnictide superconductor exhibits a Tc of 30 K, the highest of the 1111-type series in absence of chemical doping. To understand how pressure affects its electronic properties, we carried out microscopic investigations up to 3 GPa via magnetization, nuclear magnetic resonance, and muon-spin rotation experiments. The temperature dependence of the 75As Knight shift, the spin-lattice relaxation rates, and the magnetic penetration depth suggest a multi-band s-wave gap symmetry in the dirty limit, while the gap-to-Tc ratio /kBTc hints at a strong-coupling scenario. Pressure modulates the geometrical parameters, thus reducing Tc, as well as Tm, the temperature where magnetic-relaxation rates are maximized, both at the same rate of approximately -1.1 K/GPa. This decrease of Tc with pressure is consistent with band-structure calculations, which relate it to the deformation of the Fe 3dz2 orbitals.