This review stands in the larger framework of functional materials by focussing on
heterostructures of rare-earth nickelates, described by the chemical formula RNiO 3 where R …

In the past decade, the rapid development of modern heterointerface growth and
characterization techniques has stimulated great effort to research and design the …

Recently, with the improvement of the requirements for fast and efficient data processing in
the era of artificial intelligence, new forms of computing have come into being. Developing …

LaNiO3 (LNO) is the only rare-earth nickelate that does not undergo a temperature-driven
insulator–metal transition. Here, we report the successful deposition of epitaxial LNO thin …

The proton-electron coupling effect induces rich spectrums of electronic states in correlated
oxides, opening tempting opportunities for exploring novel devices with multifunctions. Here …

The recent discovery of superconductivity in hole-doped infinite-layer nickelates has
triggered a great interest in the synthesis of novel nickelate phases, which have primarily …

Interfaces between metals and semiconducting materials can inevitably influence the
magnetotransport properties, which are crucial for technological applications ranging from …

We use a 30-nm x-ray beam to study the spatially resolved properties of a SmNiO 3-based
nanodevice that is doped with protons. The x-ray absorption spectra supported by density …

Although rare-earth nickelates (ReNiO3, Re≠ La) exhibit abundant electronic phases and
widely adjustable metal to insulator electronic transition properties, their practical electronic …

The d-band correlated rare-earth nickelate (ReNiO 3) is a typical quantum material that
exhibits comparable reactivities to the noble metal oxide in oxygen evolution reactions …