Memory

The US National Institute of Standards and Technology (NIST) and its partners in the US Nanoelectronic Computing Research (nCORE) consortium have awarded $10.3 million over four years to establish a spintronics research center in Mineesota.

The Center for Spintronic Materials in Advanced Information Technologies (SMART) will be led by and housed at the University of Minnesota Twin Cities and will include researchers from the Massachusetts Institute of Technology, Pennsylvania State University, Georgetown University and the University of Maryland.

Researchers from the Tokyo Institute of Technology have developed a new thin film material made from bismuth-antimony (BiSb) that is a topological insulator that simultaneously achieves a colossal spin Hall effect and high electrical conductivity.

This material could be used as the basis of spin-orbit torque MRAM (SOT-MRAM). SOT-MRAM SOT-MRAM can overcome the limitation of spin-transfer torque in MRAM memories - and provide a much faster, denser and much more efficient memory technology. Up until now, though, no suitable material that features both high electrical conductivity and a high spin hall effect was developed.

Researchers from Mainz University demonstrate the basic principles of ultra-fast and stable memory based on the antiferromagnet Mn₂Au. Antiferromagnetic materials are challenging to manipulate and to implement a read-out process (of the Neel vector orientation on).

Up until now, researchers were only able to use a single antiferromagnetic material - copper manganese arsenide (CuMnAs), but this material had several disadvantages. The new compound, manganese and gold (Mn₂Au) offers for example ten times larger magnetoresistance and other important advantages including its non-toxic composition and the fact that it can be used even at higher temperatures.

Researchers from Japan and China have discovered the exotic dynamics of frustrated magnetic skyrmions - which are different from that of magnetic skyrmions in common ferromagnetic materials. Magnetic skyrmions are very interesting for several spintronic applications, including magnetic memory and logic computing devices.

In conventional ferromagnetic materials, the helicity (degree of freedom) of a skyrmion cannot be effectively controlled, but the researchers found that in frustrated magnetic materials it is possible to control the skyrmion helicity by utilizing the helicity locking-unlocking transition of the material. The researcher further conclude that one can use frustrated skyrmions as a binary memory utilizing two stable Bloch-type states, where the helicity can be switched by applying current.