Superconductivity and phase diagram in Sr-doped La3-xSrxNi2O7 thin films

Abstract

Recent studies have demonstrated ambient pressure superconductivity in compressively strained La3Ni2O7 thin films, yet the phase diagram of heterovalent doping-critical for advancing the field-remains unexplored. Here, we report superconductivity in Sr2+-doped La3-xSrxNi2O7 films synthesized via molecular beam epitaxy with ozone-assisted post-annealing. The superconducting transition temperature (Tc) follows an asymmetric dome-like profile, persisting across a wide doping range (0 ≤ x ≤ 0.21) before diminishing at x ≈ 0.38. Optimally doped films (x = 0.09) achieve Tc of 42 K, with high critical current (Jc > 1.4 kA/cm2 at 2 K) and upper critical fields (μ0Hc,(0)= 83.7 T, μ0Hc,(0)= 110.3 T), comparable to reported La3-xPrxNi2O7 films. Scanning transmission electron microscopy reveals oxygen vacancies predominantly occupy at planar NiO2 sites-unlike apical-site vacancies in bulk samples-due to Coulomb repulsion destabilizing planar oxygen under compressive strain. Additionally, the elongated out-of-plane Ni-O bonds, exceeding those in pressurized bulk samples by 4\%, likely weaken the interlayer dz2 coupling, thus contributing to the reduced Tc in strained films. This work establishes heterovalent Sr2+ doping as a robust tuning parameter for nickelate superconductivity, unveiling a unique phase diagram topology.