Materials challenges for SrRuO3: From conventional to quantum electronics

The need for faster and more miniaturized electronics is challenging scientists to develop novel forms of electronics based on quantum degrees of freedom different from electron charge. In this fast-developing field, often referred to as quantum electronics, the metal-oxide perovskite SrRuO3 can play an important role thanks to its diverse physical properties, which have been intensively investigated, mostly for conventional electronics. In addition to being chemically stable, easy to fabricate with high quality and to grow epitaxially onto many oxides-these are all desirable properties also for conventional electronics-SrRuO3 has interesting properties for quantum electronics like itinerant ferromagnetism and metallic behavior, strong correlation between magnetic anisotropy and spin-orbit coupling, strain-tunable magnetization, and anomalous Hall and Berry effects. In this Perspective, after describing the main phenomena emerging from the interplay between spin, orbital, lattice, and topological quantum degrees of freedom in SrRuO3, we discuss the challenges still open to achieve control over these phenomena. We then provide our perspectives on the most promising applications of SrRuO3 for devices for conventional and quantum electronics. We suggest new device configurations and discuss the materials challenges for their realization. For conventional electronics, we single out applications where SrRuO3 devices can bring competitive advantages over existing ones. For quantum electronics, we propose devices that can help gain a deeper understanding of quantum effects in SrRuO3 to exploit them for quantum technologies. We finally give an outlook about properties of SrRuO3 still waiting for discovery and applications that may stem from them. (C) 2022 Author(s).

Automated summary

The need for faster and smaller electronics has led to the exploration of quantum degrees of freedom for new forms of electronics. The metal-oxide perovskite SrRuO3 shows intriguing properties for quantum electronics, such as itinerant ferromagnetism and metallic behavior. By studying the interaction between spin, orbital, lattice, and topological quantum degrees of freedom in SrRuO3, we can gain deeper insights and explore applications in conventional and quantum electronics.