Graphene

Roland Kawakami from Ohio State University gave a lecture at Minnesota Nano Center that discusses spintronics in 2D materials, with a focus on graphene materials:

The lecture also includes opto-spintronics, 2D Magnets, and more.

Reserachers from Spain's nanoGUNE Cooperative Research Center (CIC) developed a method to connect magnetic porphyrin molecules to graphene nanoribbons. These connections may be an example of how graphene could enable the potential of molecular electronics.

Magnetic Porphyrin, a molecule that is responsible for making photosynthesis possible in plants and transporting oxygen in the blood, is an interesting spintronics material. The researchers now report that even after injecting electronic currents into the Porphyrin via the graphene wires, the molecule maintains its magnetic property. Small variations in the way the graphene nanoribbons are attached to a molecule can alter its magnetic properties - and the molecule's spin can be manipulated via the injected currents.

Researchers from the University of Nebraska-Lincoln designed a spintronics transistor that is based on graphene. The researchers say that such a device could be highly efficient, run at room temperature (and above) and feature a nonvolatile on-off current ratio and electrically controllable spin polarization.

The device is based on the discovery that an external voltage can be used to control the magnetic properties of few-layer graphene interfaced with chromium oxide. This is a theoretical research at this stage but the new device structure is expected to feature a large electrically controllable spin current.

Researchers from the University of York and Roma Tre University developed a method to build ultra-low-power transistors using composite materials based on single layers of graphene and transition metal dichalcogenides (TMDC). These materials can be used to achieve an electrical control over electron spin.

The teams explained “we found this can be achieved with little effort when 2D graphene is paired with certain semiconducting layered materials. Our calculations show that the application of small voltages across the graphene layer induces a net polarization of conduction spins".