Review on Developments and Progress in Nickelate-Based Heterostructure Composites and Superconducting Thin Films

In the past decade, the rapid development of modern heterointerface growth and characterization techniques have stimulated great effort to research and design the extraordinary physical properties of transition metal heterostructure composite materials. Here, new physics origins from the rearrangement of orbital, charge, spin, and lattice and the resulting rebalancing of their mutual interactions. In this paper, recent experimental and theoretical progresses on the design, preparation, characterization, and physical property measurement of LaNiO3-based heterostructure composites and the infinite-layer Ni1 + nickelate superconducting thin films on (001) SrTiO3 substrate are reviewed, mainly by the methods of various X-ray spectroscopy measurements, scanning transmission electron microscopy, and magneto-transport measurements. In these materials, the electronic structure and orbital occupation around the Fermi level are modified, enabling nickelate-based composite materials to exhibit new states of matter and physical phenomena, which are absent in the bulk constituents. Their confined structures, superconductivity, orbital polarization, charge transfer, electronic structures, magnetic properties, and X-ray spectroscopic analysis, are therefore highlighted, aiming at understanding unconventional superconducting mechanisms and designing new high-T-c superconducting low-dimensional materials for device applications.

Automated summary

The rapid development of modern heterointerface growth and characterization techniques in the past decade has greatly stimulated research and design efforts on the physical properties of transition metal heterostructure composite materials. In this paper, recent experimental and theoretical progresses on the design, preparation, characterization, and physical property measurement of LaNiO3-based heterostructure composites and Ni1 + nickelate superconducting thin films on SrTiO3 substrate are reviewed. The electronic structure and orbital occupation around the Fermi level are modified in these materials, enabling them to exhibit new states of matter and physical phenomena.