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Graphene is looking promising for future spintronic devices

12 April 2015

Large area graphene is able to preserve electron spin over an extended period, and communicate it over greater distances than had previously been known.

In graphene, electrons keep their magnetization, their spin (the pink arrows in the picture) much longer than they do in ordinary conductors such as copper and aluminium (image reproduced courtesy of M Venkata Kamalakar et al, Nature Communications)

This discovery, by researchers at Chalmers University of Technology in Sweden, has opened the door for the development of spintronics, with an aim to manufacturing faster and more energy-efficient memory and processors in computers. The findings are due to be published in the journal, Nature Communications.

"We believe that these results will attract a lot of attention in the research community and put graphene on the map for applications in spintronic components," says Saroj Dash, who leads the research group at Chalmers.

Spintronics is based on the quantum state of the electrons, and the technology is already being used in advanced hard drives for data storage and magnetic random accesses memory. But here the spin-based information only needs to move a few nanometres - which is lucky, because spin is a property in electrons that in most materials is extremely short-lived and fragile.

However, there are major advantages in exploiting spin as an information carrier, instead of, or in addition to, electric charges. Spintronics could make processors significantly faster and less energy consuming than they are today.

Graphene is a promising candidate for extending the use of spintronics in the electronics industry. The thin carbon film is not only an excellent electrical conductor, but also theoretically has the rare ability to maintain the electrons with the spin intact.

"In future spin-based components, it is expected that the electrons must be able to travel several tens of micrometres with their spins kept aligned," says Saroj Dash. "Metals, such as aluminium or copper, do not have the capacity to handle this. Graphene appears to be the only possible material at the moment." 

Today, graphene is produced commercially by a few companies using a number of different methods, all of which are in an early phase of development. Hitherto it has been thought that high-quality graphene can only be obtained in very small pieces, while larger graphene is produced in a way that the quality is either too low or has other drawbacks from the perspective of the electronics industry.

But that general assumption is now being seriously questioned by the findings presented by the Chalmers research group. They have conducted their experiments using CVD graphene, which is produced through chemical vapour deposition. The method gives the graphene a lot of wrinkles, roughness and other defects.

But it also has advantages: there are good prospects for the production of large area graphene on an industrial scale. CVD graphene can also be easily removed from the copper foil on which it grows and is lifted onto a silicon wafer - the semiconductor industry's standard material.

Although the quality of the material is far from perfect, the research group can now show parameters of spin that are up to six times higher than those previously reported for CVD graphene on a similar substrate.

"Our measurements show that the spin signal is preserved in graphene channels that are up to 16 micrometres long," says Chalmers researcher Venkata Kamalakar, the first author of the Nature Communications paper. "The duration over which the spins stay aligned has been measured to be over a nanosecond. This is promising because it suggests that the spin parameters can be further improved as we develop the method of manufacturing."

The goal of the research is to develop a completely new way of performing logical operations and storing information; a concept that, if successful, would take digital technology a step beyond the current dependence on semiconductors.

"Graphene is a good conductor and has no band gaps. But in spintronics there is no need for band gaps to switch between on and off, one and zero," adds Saroj Dash. "This is controlled instead by the electron's up or down spin orientations."

A short-term goal now is to construct a logical component that, not unlike a transistor, is made up of graphene and magnetic materials.


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