Research from the Universities of Bath and Exeter suggests that the use of graphene in telecommunications could improve speeds by nearly a hundred times that of current materials.
In a paper published in Physical Review Letters, researchers from the Center for Graphene Science at the Universities of Bath and Exeter have demonstrated for the first time incredibly short optical response rates using graphene, which could pave the way for a revolution in telecommunications.
Every day large amounts of information is transmitted and processed through optoelectronic devices such as optical fibers, photodetectors and lasers. Signals are sent by photons at infrared wavelengths and processed using optical switches, which convert signals into a series of light pulses.
Ordinarily optical switches respond at rate of a few picoseconds – around a trillionth of a second. Through this study physicists have observed the response rate of an optical switch using ‘few layer graphene’ to be around one hundred femtoseconds – nearly a hundred times quicker than current materials.
Graphene is just one atom thick, but remarkably strong. Scientists have suggested that it would take an elephant, balanced on a pencil to break through a single sheet. Already dubbed a miracle material due to its strength, lightness, flexibility, conductivity and low cost, it could now enter the market to dramatically improve telecommunications.
Commenting on the report’s main findings, lead researcher Dr Enrico Da Como said: “We’ve seen an ultrafast optical response rate, using ‘few-layer graphene’, which has exciting applications for the development of high speed optoelectronic components based on graphene. This fast response is in the infrared part of the electromagnetic spectrum, where many applications in telecommunications, security and also medicine are currently developing and affecting our society.”
Co-Director of the Center for Graphene Science at Bath, Professor Simon Bending added: “The more we find out about graphene the more remarkable its properties seem to be. This research shows that it also has unique optical properties which could find important new applications.”
Publication: Thomas Limmer, et al., “Carrier Lifetime in Exfoliated Few-Layer Graphene Determined from Intersubband Optical Transitions,” Phys. Rev. Lett. 110, 217406 (2013); doi:10.1103/PhysRevLett.110.217406
Source: University of Bath
Image: Graphene Molecular Structure from Shuteterstock