Pressure-induced superconductivity in epitaxially-stabilized Pr3Ni2O7 films

Abstract

The discovery of high critical-temperature Tc superconductivity in La3Ni2O7 under high pressure has led to a rapid expansion of the Tc range through lanthanide Ln substitution, and to ambient-pressure superconductivity in strained thin films, yet the exploration of new bilayer nickelates remains strongly constrained by thermodynamic stability. Beyond the difficulty of synthesis of bulk single-crystals, here we report on the pressure-induced high-Tc superconductivity in epitaxially-stabilized Pr3Ni2O7 thin films. While the Pr3Ni2O7 films exhibit insulating behaviour at ambient pressure regardless of ozone-annealing treatment, they show T-linear metallic transport and superconductivity reaching an onset Tc of 66 K and zero-resistance at nearly 40 K at 22 GPa. Furthermore, Nd3Ni2O7, with the smaller rare-earth ion Nd, can also be stabilized, however, superconductivity is not observed in the measured pressure range. Epitaxial stabilization enables us to examine the dependence of Tc and the critical pressure Pc for superconductivity on the Ln ion in Ln3Ni2O7 (Ln = La, Pr, Nd). These results suggest that a higher Pc is required for smaller Ln ions, consistent with trends observed in bulk studies of Ln substitution. This study demonstrates that epitaxial stabilization is a powerful technique to further expand the family of superconducting bilayer nickelates.