Distinct Roles of Hydrogen in Superconducting and Ferromagnetic Phases of CoZr2Hx

Abstract

Hydrogenation offers a versatile route to tuning the physical properties of intermetallic compounds. In this study, we synthesized CoZr2Hx with different hydrogen contents and found that hydrogen is incorporated in two distinct concentration regimes separated by a wide composition gap: a low-concentration hydrogenated superconducting phase (x = 0-0.054) and a high-concentration hydrogenated ferromagnetic phase (x = 2.786). Hydrogen plays fundamentally different roles in the two concentration regimes. In the high hydrogen concentration phase, the Zr-H interactions substantially modify the metallic bands crossing the Fermi level, leading to the emergence of ferromagnetism. In contrast, in the low hydrogen concentration phase, hydrogen behaves as a nonmagnetic impurity without altering the electronic band structure. Despite the nearly identical Debye temperatures across the low-concentration series, the superconducting transition temperature (Tc) is progressively suppressed with increasing hydrogen content.The observed Tc suppression is quantitatively described by the Abrikosov-Gor'kov pair-breaking theory, indicating that the superconducting gap of CoZr2 is anisotropic or multigap rather than a fully isotropic s-wave symmetry.