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How graphene semiconductors can revolutionise electronics and computing

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Scientists have unveiled the first functional graphene semiconductor, paving the way for much faster and more energy-efficient electronic devices.

Scientists have unveiled the first functional graphene semiconductor, paving the way for much faster and more energy-efficient electronic devices.
| Photo Credit: Imaginechina-Tuchong/imago images

Researchers have showcased the first functional graphene semiconductor. The discovery could change computing and electronics forever. Scientists have made a breakthrough in electronics, creating the world’s first functional semiconductor made from graphene—a material known for being tough, flexible, light and with a high resistance.

Their discovery comes at a time when silicon, the material from which nearly all modern electronics are made, is reaching its limit. Scientists have been racing to develop graphene semiconductors because of their superior speed and energy efficiency compared to silicon.

The study, published in Nature on January 3, demonstrates a functional graphene semiconductor which is suitable for use in nanoelectronics. The authors said the discovery could mark a major step toward the next generation of computing, throwing open the doors to a new way of building electronics.

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“We don’t know where this will end but we know we’re opening the door for a major paradigm shift in electronics,” said lead author Walter de Heer of the Georgia Institute of Technology in the US in a press release. “Graphene is the next step. Who knows what the next steps are after that, but there’s a good chance graphene could take over be the paradigm for the next fifty years.”

Silicon semiconductors are reaching their limit

Classical computers like the chip in your phone or laptop use electricity flowing through silicon switches to represent ones and zeros—also known as bits.

“Semiconductors are essential to allow all computers to function. They allow us to create tiny switches which can be turned on and off to allow the flow of electricity. It is this electricity flowing through electrical circuits that allows computers to perform calculations,” said Sarah Haigh, professor of materials at the National Graphene Institute, University of Manchester, UK.

We use silicon semiconductors every time we use a credit card, start a car, open doors on buses and trains and of course use a smartphone or laptop. But silicon semiconductors have their limitations, which has led scientists to search for a new material.

“Silicon electronics require a fairly large amount of power and energy, including energy needed to cool the electronics when energy is emitted as heat,” said Haigh.

Graphene: Wonder material

One option was graphene. Graphene is a single sheet of carbon atoms—a 2D material held together by the strongest chemical bonds known. These carbons are arranged in tessellated hexagons, much like honeycomb.

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It is an incredibly strong material—about 200 times stronger than steel. It’s so strong you can hold up a football with just one atomic layer of graphene. Graphene is also incredibly flexible, making it ideal for use in electrical devices and batteries, or even printed on glass, plastics or fabrics. But its potential to be used as a faster and more energy-efficient semiconductor has excited scientists the most.

“The possibility to retain graphene’s exceptional speed as well as the efficiency of the conduction of electrons without requiring large amounts of energy offers huge potential for it to be used to create ‘beyond silicon’ electronics where computers are faster and use less energy to run,” said Haigh.

First functional graphene superconductor

Graphene has major drawbacks, which has prevented its use in electronics. One major issue is known as the “band gap problem.” Haigh said. “Scientists in the field have been trying to realize the exceptional conductivity of graphene in electronic circuits for over a decade”.

The band gap is a crucial electronic property that allows semiconductors to switch on and off. Graphene didn’t have a band gap—until now. De Heer’s team figured out how to grow graphene on special silicon carbide chips. The research took 10 years, as the team refined materials and altered graphene’s chemical properties until they achieved the perfect structure.

Finally, the graphene was able to act like a high-quality semiconductor that rivalled silicon. “The good thing about graphene is, not only can you make things smaller and faster and with less heat dissipation, you’re using properties of electrons that are not accessible in silicon. So this is a paradigm shift—it’s a different way of doing electronics,” said de Heer.

Faster, more energy-efficient electronics

Experts say the innovation holds huge potential for the electronics industry. For one thing, it could allow us to create new graphene semiconductors which are much more powerful, but use less energy than their silicon counterparts.

“Graphene electronics are more efficient because they can require less energy to switch on and off. They also allow electrons to flow without creating a lot of unwanted heat that has to be cooled with fans [requiring energy],” said Haigh. “This would mean phones could last for weeks without running out of battery, reduce energy consumption in all parts of our lives, reducing costs and the pollution from fossil fuels,” she added.

De Heer said his discovery could change the future of electronics. For one, the new graphene superconductors could accelerate the development of quantum computing technologies. Quantum computers can solve problems in seconds that would take ordinary supercomputers millennia to do, but they’re still in development. Experts say graphene semiconductors could help overcome the many challenges of creating quantum computers.

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