Strong-coupling anisotropic superconductivity in hexagonal HfRuAs from anisotropic Migdal-Eliashberg theory

Abstract

We present a comprehensive theoretical investigation of the superconducting (SC) properties of hexagonal HfRuAs (h-HfRuAs) by solving anisotropic Migdal--Eliashberg (ME) equations with the inputs from ab initio calculations of electronic structure, phonon dispersion and electron phonon coupling matrix elements. The calculated Eliashberg spectral function reveals strong electron--phonon coupling (EPC) with a constant λ≈ 1.56, dominated by low-frequency phonon modes associated primarily with Hf and Ru vibrations. The SC state is characterized by a single anisotropic gap with overall s-wave symmetry, as evidenced by the fully gapped quasiparticle density of states. The momentum-resolved EPC and SC gap exhibit pronounced anisotropy across different Fermi surface sheets, with the largest variations occurring on the hole-like bands. The SC gap is centered around Δ≈ 2.9 meV with a spread of 0.8 meV, indicating significant multiband anisotropy. The resulting gap ratio 2Δ(0)/kB Tc ≈ 4.2 exceeds the BCS weak-coupling limit, establishing h-HfRuAs as a strong-coupling superconductor. The calculated transition temperature, Tc, agrees in the order of magnitude with experiments. Overall, our results identify h-HfRuAs as a phonon-mediated, strongly coupled anisotropic superconductor and provide detailed insights into the role of momentum-dependent electron--phonon interactions in determining its SC properties.