Prediction of Ambient-Pressure High-Temperature Superconductivity in Doped Transition-Metal Hydrides

Abstract

The search for conventional superconductors with high transition temperatures (Tc) has largely focused on intrinsically metallic compounds. In this work, we explore the potential of intrinsically non-metallic compounds to exhibit high-Tc superconductivity under ambient pressure through carrier doping. We identify MgAlFeH6, a representative of carrier-doped transition-metal hydrides like Mg2FeH6, as a promising example with a predicted Tc ≈ 130~ K. We propose that the average projected electron density of states, defined as the geometric mean of the total and hydrogen-projected density of states at the Fermi level, serves as a simple and computationally inexpensive indicator of high-Tc behavior. We also highlight the tradeoff between high-Tc and dynamic stability, both of which depend on the electron density of states. Our findings thus expand the pool of potential superconducting materials and offer a practical route for accelerating the discovery of superconductors suitable for real-world applications.