Ultrathin epitaxial MgB2 on SiC: Substrate surface-polarity-dependent properties

High-quality, ultrathin superconducting films are required for advanced devices such as hot-electron bolometers, superconducting nanowire single-photon detectors, and quantum applications. Using hybrid physical-chemical vapor deposition, we show that MgB2 films as thin as 4 nm can be fabricated on the carbon-terminated 6H-SiC (0001) surface with a superconducting transition temperature above 33 K and a rms roughness of 0.7 nm. Remarkably, the film quality is a function of the SiC surface termination, with the C-terminated surface preferred to the Si-terminated surface. To understand the MgB2 thin film/SiC substrate interactions giving rise to this difference, we characterized the interfacial structures using Rutherford backscat- tering spectroscopy/channeling, electron-energy-loss spectroscopy, and x-ray photoemission spectroscopy. The MgB2/SiC interface structure is complex and different for the two terminations. Both terminations incorporate substantial unintentional oxide layers influencing MgB2 growth and morphology, but with a different extent, intermixing, and interface chemistry. In this paper, we report measurements of transport, resistivity, and the critical superconducting temperature of MgB2/SiC that are different for the two terminations, and they link interfacial structure variations to observed differences. The result shows that the C face of SiC is a preferred substrate for the deposition of ultrathin superconducting MgB2 films.

Automated summary

This study demonstrates the fabrication of ultrathin MgB2 films with a thickness of only 4 nm on the carbon-terminated 6H-SiC (0001) surface using hybrid physical-chemical vapor deposition. The film exhibits a high superconducting transition temperature of above 33 K and a low rms roughness of 0.7 nm. The research also reveals that the quality of the MgB2 film is influenced by the termination of the SiC surface, with the carbon-terminated surface favored over the silicon-terminated surface.