The discovery of superconductivity in the Ba-La-Cu-O system (the cuprate) in the 30 K range marked a significant breakthrough, which inspired extensive explorations of oxide based layered superconductors to identify electron pairing with higher critical temperatures (_T_c)1. Despite recent observations of superconductivity in nickel-oxide-based compounds (the nickelates), evidence of Cooper pairing above 30 K in a system that is isostructural to the cuprates, but without copper, at ambient pressure and without lattice compression, has remained elusive2–5. Here, we report superconductivity with a _T__c_ approaching 40 K under ambient pressure in the _d_9-_x_ hole-doped, late rare-earth infinite-layer nickel oxide (Sm-Eu-Ca-Sr)NiO2 thin films with negligible lattice compression, supported by observations of a zero resistance state at 31 K and the Meissner effect. The material can be synthesized with essentially no Ruddlesden–Popper type structural defects, exhibiting ultralow resistivity of ~ 0.01 mΩ∙cm with a residual-resistivity-ratio of up to 10. Our findings demonstrate the potential of achieving high-temperature superconductivity using strongly correlated _d_\-electron metal oxides beyond copper as the building blocks for superconductivity, offering a promising platform for further exploration and understanding of high-temperature Cooper pairing.
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This file includes Supplementary Discussion, Supplementary Tables 1-2, Supplementary Figures 1-7, and Supplementary References.