Anomalous metallic state and anisotropic multiband superconductivity in Nb3Pd0.7Se7

Abstract

We report the discovery of superconductivity in Nb3PdxSe7 with a x-dependent superconducting transition-temperature as high as Tc 2.1 K for x 0.7 (middle point of the resistive transition). Needle-like single crystals display anisotropic upper-critical fields with an anisotropy γ = Hbc2/Hac2 as large as 6 between fields applied along their needle axis (or b-axis) or along the a-axis. As for the Fe based superconductors γ is temperature-dependent suggesting that Nb3Pd0.7Se7 is a multi-band superconductor. This is supported by band structure calculations which reveal a Fermi surface composed of quasi-one-dimensional and quasi-two-dimensional sheets of hole character, as well as three-dimensional sheets of both hole- and electron-character. Remarkably, Hbc2 is observed to saturate at Hbc2(T → 0 K) 14.1 T which is 4.26 × Hp where Hp is the Pauli-limiting field in the weak-coupling regime. The synthesis procedure yields additional crystals belonging to the Nb2PdxSe5 phase which also becomes superconducting when the fraction of Pd is varied. For both phases we find that superconductivity condenses out of an anomalous metallic state, i.e. displaying ∂ / ∂ T < 0 above Tc similarly to what is observed in the pseudogap-phase of the underdoped cuprates. An anomalous metallic state, low-dimensionality, multi-band character, extremely high and anisotropic Hc2s, are all ingredients for unconventional superconductivity.