Research uncovers surface current behaviour of Si(111)-(√7 x √3)-In
Researchers at the International Center for Materials Nanoarchitectonics, Tsukuba have uncovered the underlying structures and the behaviour of currents on the surface of Si(111) which provide clues to its superconductivity. Superconductors have effectively zero resistance and act as perpetual carriers of electric current with no need for a connected power source, giving rise to many applications in electronics.
One of the thinnest two-dimensional materials ever created, called Si(111)-(√7 x √3)-In, comprised of individual indium atoms added to a silicon surface, recently surprised scientists with its superconducting abilities. The race is now on to find out how and why this silicon surface is capable of superconductivity, as well as what uses it may have.
Takashi Uchihashi and co-workers at the International Center for Materials Nanoarchitectonics, Tsukuba, together with scientists across Japan, have now uncovered the underlying structures and the behavior of currents on the surface of Si(111)-(√7 x √3)-In which provide clues to its superconductivity.
The silicon surface comprises individual terraces separated by steps measuring the height of a single atom (‘atomic steps’). These steps could potentially interrupt, or decouple, neighbouring terraces and break the current flowing over large surfaces. Uchihashi and his team used a scanning tunnelling microscope in order to verify how superconductivity occurs in the presence of atomic steps and terraces. The team applied different magnetic fields, which influenced the strength of the current and the presence of associated vortices.
By taking a series of images of the silicon, the team uncovered a pattern of supercurrent vortices present on the silicon surface. Two vortex types were present. Pearl vortices were present on the terrace surfaces, and appeared as bright round features in the images. However, at the atomic steps the vortices appeared to become trapped and altered in character. These elongated ‘Josephson vortices’ indicated that the atomic steps work as so-called Josephson junctions, allowing coupling to occur across stepped terraces and enabling supercurrents to flow.