Searching for Superconductivity in High Entropy Oxide Ruddlesden-Popper Cuprate Films

TL;DR

This study investigates high entropy oxide cuprate films to find superconductivity, revealing that structural distortions prevent superconductivity despite doping and oxygen tuning, highlighting the importance of cation size variance.

Contribution

It demonstrates that high entropy oxide cuprates do not exhibit superconductivity due to lattice distortions caused by cation size variance, providing insights into structural effects on electronic properties.

Findings

All films are insulating regardless of doping.

Resistivity can be tuned by oxygen stoichiometry but no superconductivity observed.

Large Cu-O plane distortion likely causes charge localization.

Abstract

In this work, the high entropy oxide A2CuO4 Ruddlesden-Popper (La0.2Pr0.2Nd0.2Sm0.2Eu0.2)2CuO4 is explored by charge doping with Ce+4 and Sr+2 at concentrations known to induce superconductivity in the simple parent compounds, Nd2CuO4 and La2CuO4. Electron doped (La0.185Pr0.185Nd0.185Sm0.185Eu0.185Ce0.075)2CuO4 and hole doped (La0.18Pr0.18Nd0.18Sm0.18Eu0.18Sr0.1)2CuO4 are synthesized and shown to be single crystal, epitaxially strained, and highly uniform. Transport measurements demonstrate that all as-grown films are insulating regardless of doping. Annealing studies show that resistivity can be tuned by modifying oxygen stoichiometry and inducing metallicity but without superconductivity. These results in turn are connected to extended x-ray absorption fine structure (EXAFS) results indicating that the lack of superconductivity in the high entropy cuprates likely originates from a large distortion within the Cu-O plane ({\sigma}2>0.015 {\AA}2) due to A-site cation size variance, which drives localization of charge carriers. These findings describe new opportunities for controlling charge- and orbital-mediated functional responses in Ruddlesden-Popper crystal structures, driven by balancing of cation size and charge variances that may be exploited for functionally important behaviors such as superconductivity, antiferromagnetism, and metal-insulator transitions, while opening less understood phase spaces hosting doped Mott insulators, strange metals, quantum criticality, pseudogaps, and ordered charge density waves.