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University of Cambridge - telecommunication

Researchers demonstrate the UK’s first long-distance ultra-secure communication over a quantum network Client Challenge Existing infrastructure will be unable to support demand for high-speed internet Graphene may exceed bandwidth demands of future telecommunications BT and Huawei announce five year collaboration with Cambridge New light shed on explosive solar activity Graphene goes plasmonic Paranoid Android? Get connected to a new study… Democratising the airwaves
Graphene paves the way to faster high-speed communications
Anonymous · 2018-05-31 · via University of Cambridge - telecommunication

Researchers have created a technology that could lead to new devices for faster, more reliable ultra-broad bandwidth transfers, and demonstrated how electrical fields boost the non-linear optical effects of graphene. 

Graphene, among other materials, can capture particles of light called photons, combine them, and produce a more powerful optical beam. This is due to a physical phenomenon called optical harmonic generation, which is characteristic of nonlinear materials. Nonlinear optical effects can be exploited in a variety of applications, including laser technology, material processing and telecommunications.

Although all materials should demonstrate this behaviour, the efficiency of this process is typically small and cannot be controlled externally. Now, researchers from the University of Cambridge, Politecnico di Milano and IIT- Istituto Italiano di Tecnologia have demonstrated that graphene not only shows a good optical response but also how to control the strength of this effect using an electric field. Their results are reported in the journal Nature Nanotechnology. All three institutions are partners in the Graphene Flagship, a pan-European project dedicated to bringing graphene and related materials for commercial applications.

What is graphene?

Graphene – a form of carbon just a single atom thick – has a unique combination of properties that make it useful for applications from flexible electronics and fast data communication, to enhanced structural materials and water treatments. It is highly electrically and thermally conductive, as well as strong and flexible.

How could graphene be useful?

Researchers envision the creation of new graphene optical switches, which could also harness new optical frequencies to transmit data along optical cables, increasing the amount of data that can be transmitted. Currently, most commercial devices using nonlinear optics are only used in spectroscopy. Graphene could pave the way towards the fabrication of new devices for ultra-broad bandwidth applications.

“Our work shows that the third harmonic generation efficiency in graphene can be increased by over 10 times by tuning an applied electric field,” said lead author Giancarlo Soavi, of the Cambridge Graphene Centre.

“The authors found again something unique about graphene: tuneability of third harmonic generation over a broad wavelength range," said Professor Frank Koppens from the ICFO (The Institute of Photonic Sciences)in Barcelona and leader of one of the Graphene Flagship work packages. "As more and more applications are all-optical, this work paves the way to a multitude of technologies.”

Professor Andrea C Ferrari, Science and Technology Officer of the Graphene Flagship, and Chair of its Management Panel, said: “Graphene never ceases to surprise us when it comes to optics and photonics. The Graphene Flagship has put significant investment to study and exploit the optical properties of graphene. This collaborative work could lead to optical devices working on a range of frequencies broader than ever before, thus enabling a larger volume of information to be processed or transmitted.”

More about this topic

Reference: Giancarlo Soavi et al. 'Broadband, electrically tuneable, third harmonic generation in graphene.' Nature Nanotechnology (2018). DOI: 10.1038/s41565-018-0145-8

This article was adapted from a Cambridge Graphene Centre press release. Read the original press release from the Cambridge Graphene Centre