Electron-phonon superconductivity in C-doped topological nodal-line semimetal Zr5Pt3: A muon spin rotation and relaxation (μSR) study

Abstract

In the present work we demonstrate that C-doped Zr5Pt3 is an electron-phonon superconductor (with critical temperature TC = 3.7\,K) with a nonsymmorphic topological Dirac nodal-line semimetal state, which we report here for the first time. The superconducting properties of Zr5Pt3C0.5 have been investigated by means of magnetization and muon spin rotation and relaxation (μSR) measurements. We find that at low temperatures the depolarization rate is almost constant and can be well described by a single-band s-wave model with a superconducting gap of 2(0)/kBTC = 3.84, close to the value of BCS theory. From transverse field μSR analysis we estimate the London penetration depth λL = 469 nm, superconducting carrier density ns = 2×1026 m-3, and effective mass m* = 1.584 me. Zero field μSR confirms the absence of any spontaneous magnetic moment in the superconducting ground state. To gain additional insights into the electronic ground state of C-doped Zr5Pt3, we have also performed first-principles calculations within the framework of density functional theory (DFT). The observed homogenous electronic character of the Fermi surface as well as the mutual decrease of TC and density of states at the Fermi level are consistent with the experimental findings. However, the band structure reveals the presence of robust, gapless fourfold-degenarate nodal lines protected by 63 screw rotations and glide mirror planes. Therefore, Zr5Pt3 represents a novel, unprecedented condensed matter system to investigate the intricate interplay between superconductivity and topology.