Persistent structural distortions and absent superconductivity in trilayer nickelate thin films

Abstract

A new family of high-temperature superconductors was recently discovered in the n=2,3 Ruddlesden-Popper nickelates, where superconductivity emerges concomitant with suppression of parent density waves and structural octahedral rotations under hydrostatic pressure. Intriguingly, compressive strain mimics the structural effects of pressure in the n=2 phase, yielding ambient-pressure superconductivity. However, analogous strain-stabilized superconductivity has not been realized in the n=3. Here, we use atomically-precise synthesis, transport, picoscale electron microscopy, and synchrotron X-ray diffraction to probe n=3 La4Ni3O10 thin films. Although compressive strain suppresses density wave order, we do not observe superconductivity even under the largest strain state. Importantly, we identify a structural distortion unique to strained n=3 thin films that may inhibit superconductivity: persistent, layer-inequivalent octahedral rotations around the c-axis. Our results highlight key differences between the n=3 and n=2 systems, suggesting that ambient-pressure superconductivity in the n=3 may require new methods beyond epitaxial strain engineering.