The new nanotextured graphene sheet could be used to produce flexible solar cells. Photo: University of Surrey.
The new nanotextured graphene sheet could be used to produce flexible solar cells. Photo: University of Surrey.

New research published in Science Advances shows how graphene can be manipulated to create the most light-absorbent material for its weight developed to date. This nanometre-thin material could lead to 'smart wallpaper' that can generate electricity from waste light or heat and also power a host of applications within the growing 'internet of things'.

Taking inspiration from the structure of moth’s eyes, researchers from the Advanced Technology Institute at the University of Surrey in the UK have created ultra-thin graphene sheets designed to capture light more effectively. Just one atom thick, graphene is very strong but has traditionally been inefficient at absorbing light. To combat this, the team employed a technique known as nanotexturing, which involves growing graphene around a textured metallic surface, to localize light into the narrow spaces between the textured surface, enhancing the amount of light absorbed by the material by about 90%.

"Nature has evolved simple yet powerful adaptations, from which we have taken inspiration in order to answer challenges of future technologies," explained Ravi Silva, head of the Advanced Technology Institute. "Moths' eyes have microscopic patterning that allows them to see in the dimmest conditions. These work by channeling light towards the middle of the eye, with the added benefit of eliminating reflections, which would otherwise alert predators of their location. We have used the same technique to make an amazingly thin, efficient, light-absorbent material by patterning graphene in a similar fashion."

Graphene has already been noted for its remarkable electrical conductivity and mechanical strength. Silva and his team understood that for graphene's potential to be realized as a material for future applications, it should also harness light and heat effectively.

"Solar cells coated with this material would be able to harvest very dim light," said Silva. "Installed indoors, as part of future 'smart wallpaper' or 'smart windows', this material could generate electricity from waste light or heat, powering a numerous array of smart applications. New types of sensors and energy harvesters connected through the Internet of Things would also benefit from this type of coating."

"As a result of its thinness, graphene is only able to absorb a small percentage of the light that falls on it," added lead author José Anguita. "For this reason, it is not suitable for the kinds of optoelectronic technologies our 'smart' future will demand. Nanotexturing graphene has the effect of channeling the light into the narrow spaces between nanostructures, thereby enhancing the amount of light absorbed by the material. It is now possible to observe strong light absorption from even nanometre-thin films. Typically, a graphene sheet would have 2–3% light absorption. Using this method, our ultrathin coating of nanotextured few-layer graphene absorbs 95% of incident light across a broad spectrum, from the UV to the infrared."

"The next step is to incorporate this material in a variety of existing and emerging technologies," Silva concluded. "We are very excited about the potential to exploit this material in existing optical devices for performance enhancement, whilst looking towards new applications. Through Surrey's EPSRC-funded Graphene Centre, we are looking for industry partners to exploit this technology and are keen to hear from innovative companies who we can explore the future applications of this technology with us."

The Surrey team developed this technology in cooperation with the British defense company BAE Systems for infrared imaging in opto-MEMs devices.

This story is adapted from material from the University of Surrey, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.