Probing the superconducting ground state of the rare-earth ternary boride superconductors RRuB2 (R = Lu,Y) using muon-spin rotation and relaxation

Abstract

The superconductivity in the rare-earth transition metal ternary borides RRuB2 (where R = Lu and Y) has been investigated using muon-spin rotation and relaxation. Measurements made in zero-field suggest that time-reversal symmetry is preserved upon entering the superconducting state in both materials; a small difference in depolarization is observed above and below the superconducting transition in both compounds, however this has been attributed to quasistatic magnetic fluctuations. Transverse-field measurements of the flux-line lattice indicate that the superconductivity in both materials is fully gapped, with a conventional s-wave pairing symmetry and BCS-like magnitudes for the zero-temperature gap energies. The electronic properties of the charge carriers in the superconducting state have been calculated, with effective masses m*/ me = 9.80.1 and 15.00.1 in the Lu and Y compounds, respectively, with superconducting carrier densities ns = (2.730.04) × 1028 m-3 and (2.170.02) × 1028 m-3. The materials have been classified according to the Uemura scheme for superconductivity, with values for Tc/TF of 1/(4146) and 1/(3043), implying that the superconductivity may not be entirely conventional in nature.