Unexpected orbital magnetism in Bi-rich Bisub2/subSesub3/sub nanoplatelets

摘要

Plate-like bismuth nanocrystals can give physicists enriched mechanisms to control spin through unexpected, surface-localized magnetism. Topological insulators have crystal structures that make them non-conductive everywhere except for the quantized states on their surfaces. Hae Jin Kim's group at KBSI and co-workers (PI, “Demokritos”, and UoI) has now used a liquid-phase, solvothermal synthesis to turn bismuth selenide (Bi2Se3) topological insulators into nanometre-thin platelets with unique hexagonal shapes. The team discovered that sandwiching bismuth atoms between the nanohexagons disrupts the normal coupling interactions between electron spin and orbital motion at topological insulators surface states. This splitting generates so-called Rashba states that produce a special orbital-based type of magnetism, where spin states can be flipped with help from a weak magnetic field. Further spin engineering of this system is possible by altering the degree of bismuth intercalation.