EPJ D Highlight - Creating optical logic gates from graphene nanoribbons

Logic gate operation in a graphene nanoribbon

A new graphene-based optical logic gate uses collective oscillations of electrons to process light waves in a far smaller space than existing designs. The device also benefits from low information loss and high stability.

Research into artificial intelligence (AI) network computing has made significant progress in recent years, but has so far been held back by the limitations of logic gates in conventional computer chips. Through new research published in EPJ D, a team led by Aijun Zhu at Guilin University of Electronic Technology, China, introduce a graphene-based optical logic gate, which addresses many of these challenges.

The design could lead to a new generation of computer chips which consume less energy, while reaching higher computing speeds and efficiencies. This could in turn pave the way for the use of AI in computer networks to automate tasks and improve decision making – leading to enhanced performance, security, and functionality.

There are many advantages to microchips whose component logic gates exchange signals using light, instead of electrical current. However, current designs are often bulky, somewhat unstable, and vulnerable to information loss.

In their paper, Zhu’s team introduce a graphene-based alternative, composed of Y-shaped graphene nanoribbons bonded on top of a layer of insulation. This design is ideal for hosting plasmon waves: collective oscillations of electrons which arise at the interface between the graphene and the insulating medium. They can be triggered by the light waves in incoming optical signals, and can also generate outgoing signals themselves after the information is processed by the logic gate.

Since surface plasmon wavelengths are shorter than those of optical light waves, the researchers show that their setup can become far more compact than previous designs of optical logic gates. Their device can be switched on and off using an external voltage, which manipulates the energy levels at which electrons in graphene are available for conveying electrical current.

In their experiments, Zhu’s team achieved an impressively high ratio between the power level of their gate’s ‘on’ and ‘off’ states, where it transmits and blocks data, respectively. As well as outperforming previous optical logic gates, their design also benefits from a small size, low loss of information, and high stability.

This was our first experience of publishing with EPJ Web of Conferences. We contacted the publisher in the middle of September, just one month prior to the Conference, but everything went through smoothly. We have had published MNPS Proceedings with different publishers in the past, and would like to tell that the EPJ Web of Conferences team was probably the best, very quick, helpful and interactive. Typically, we were getting responses from EPJ Web of Conferences team within less than an hour and have had help at every production stage.
We are very thankful to Solange Guenot, Web of Conferences Publishing Editor, and Isabelle Houlbert, Web of Conferences Production Editor, for their support. These ladies are top-level professionals, who made a great contribution to the success of this issue. We are fully satisfied with the publication of the Conference Proceedings and are looking forward to further cooperation. The publication was very fast, easy and of high quality. My colleagues and I strongly recommend EPJ Web of Conferences to anyone, who is interested in quick high-quality publication of conference proceedings.

On behalf of the Organizing and Program Committees and Editorial Team of MNPS-2019, Dr. Alexey B. Nadykto, Moscow State Technological University “STANKIN”, Moscow, Russia. EPJ Web of Conferences vol. 224 (2019)

ISSN: 2100-014X (Electronic Edition)

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