Spin injection in semiconductors has been a long-standing issue in the field of spintronics for nearly 10 years. Only at the end of the 1990s, electrical spin injection ill Ill-V semiconductors could be demonstrated using spin-light emitting diodes as spin detectors. Although Silicon is the key material of microelectronics, spin injection ill Silicon Could be achieved only recently in 2007. For this purpose, we have developed a new ferromagnetic semiconductor (Ge,Mn) that may be suitable for spin injection in silicon. Indeed this material is compatible with mainstream silicon technology and is predicted as a half-metallic ferromagnet. We have used low temperature molecular beam epitaxy to grow germanium films doped with manganese. Growth temperatures as well as Mn concentrations were kept low in order to avoid phase separation due to the low Solubility of Mn in Ge. Careful structural and chemical analyses showed that (Ge, Mn) Films are not diluted magnetic semiconductors. We rather observe high-T(C) ferromagnetic self-assembled nanocolumns in the germanium film With magnetic properties strongly dependent oil growth parameters. We could clearly identify four different magnetic phases in Ge(1-x)Mn(x) films: diluted paramagnetic Mn atoms in the germanium matrix, low T(C) (<200 K) nanocolumns, high T(C) nanocolumns (>400 K) and Ge(3)Mn(5) clusters. The relative weight of each phase mainly depends oil the growth temperature and to a lesser extent to Mn concentration. In parallel, we have developed methods to detect spin injection in silicon. Using a ferromanetic metal with perpendicular magnetisation we Could perform spin injection in silicon in the tunnelling regime through ail alumina barrier. Spin detection was Optically achieved using a SiGe/Si spin-light emitting diode without applying a magnetic field.

• 出版日期2010
• 单位中国地震局