Single or assemblies of magnetic atoms positioned on non-magnetic substrates have great potential in high density magnetic data storage and quantum computing applications. However, they suffer the limitation that the magnetic moments of these atoms are easily destabilized by interactions with the substrate, resulting in very short lifetimes.
An international team including researchers from Karlsruhe Institute of Technology (KIT), the Max Planck Institute (MPI) of Microstructure Physics in Halle, the University of Leipzig, Germany, and the University of Tokyo, Japan, have now found a route to overcome this problem, as described in November 14 issue of Nature (DOI:10.1038/nature12759; p. 242). An individual holmium atom was fixed to a metal surface so that the spin of one holmium electron remains stable for more than 10 minutes. The spin can be descriptively understood as a rotation direction of an electron, giving it a magnetic moment that can align itself in a particular direction in an external magnetic field. A network of several hundred million atoms is necessary for a magnetic bit to remain stable enough for hard disk data to remain safe for years.
“One individual atom fixed to a substrate is usually so sensitive that it keeps its magnetic orientation for mere fractions of a microsecond (200 nanoseconds),” said co-author Wulf Wulfhekel from KIT. Their current research, Wulfhekel said, “not only opens the door to denser computer storage devices, but could also lay the foundation for constructing quantum computers.”
In their latest experiment, the researchers placed one individual atom of the rare-earth metal holmium onto a platinum substrate. At temperatures around –272°C, they used scanning tunneling microscopy to measure how the spin of the atom and thus its magnetic moment aligns. They observed that it was almost 10 minutes before the magnetic moment changed its direction. “So once the system has established its magnetic spin, it keeps it for a billion times longer than comparable atomic systems,” said Wulfhekel.
Normally, the electrons of the substrate and the atom interact frequently with each other on the quantum mechanical level and destabilize the spin of the atom in microseconds or faster. Holmium and platinum form a quantum system whose symmetry properties switch off the interfering interactions at very low temperatures. “Basically, holmium and platinum are mutually invisible, as far as the spin scattering is concerned,” said Arthur Ernst of MPI in Halle and the University of Leipzig. With the aid of external magnetic fields, however, it is possible to align the spin of the holmium and thus to write information. This is precisely what the team of researchers now wants to attempt. If they are successful, this would lay the foundations for the development of compact data-storage devices or quantum computers.