November 21, 2018

Good Morning,

Graphene is being incorporate into electronic displays to consuming less energy, while yielding high resolutions and faster frame rates. Nice!

Learn about this and more interesting stories from the scientific community in today's issue.

Until Next Time,
Erin

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*-- Graphene to power higher resolution, energy-efficient electronic displays --*

Scientists in the Netherlands have found a way to incorporate graphene into electronic displays, yielding high resolutions and faster frame rates, while consuming less energy.

Better displays are needed for the next generation of electronics, like virtual reality systems. The best electronic displays in use today, like those found on smartphones, require significant amounts of energy from batteries.

Reflective displays, like those found on e-book readers, use small amounts of energy, but don't feature the speed or resolution to support standard technologies like OLED or LCD.

With graphene, however, scientists were able to create a reflective display capable of higher resolutions and faster frame rates.

Graphene is made up of a one-atom thick sheet of carbon atoms arranged in a honeycomb-like structure. It is strong, flexible, lightweight, nearly transparent and a superb conductor of heat and electricity. The carbon sheet is ideal for use in the construction of micro-electromechanical systems, or MEMs.

Once graphene is incorporated into a MEM, membranes in the display can be manipulated using electrical and optical inputs.

"Graphene is a versatile material with excellent mechanical, optical and electrical properties, and the combination of all of them enables the GIMOD technology," lead researcher Samer Houri, nanoscientist at Delft University of Technology, said in a news release.

In the GIMOD display, pixels are composed of electrically controlled membranes, which reflect incoming white light. The graphene membranes flicker at speeds imperceptible to the human eyes.

According to the researchers, the new technology held its own during side-by-side comparisons with traditional electronic displays.

"We showcased GIMOD prototypes of 2500 pixels per inch in the Mobile World Congress, and many players from the display industry reacted quite enthusiastically," said Cartamil-Bueno, creator of the graphene display. "While participating in several business contests in Germany, I have been preparing the team and securing capital. In few weeks, we will launch the startup to commercialize GIMOD components, aiming to tackle the VR market because that is where GIMOD outperforms every other technology."

Researchers described the development of their GIMOD display in a new paper published Friday in the journal Nature Communications.

*-- Air could replace silicon in the next generation of nanochips --*

Electrical engineers have developed a new type of transistor capable of sending electrons across tiny gaps of air instead of silicon. The development negates the need for a semiconductor, making the device faster and less likely to overheat.

Researchers used the breakthrough to develop a proof-of-concept design for a nanochip featuring a combination of metal and narrow air gaps. The team of engineers detailed their invention in the journal Nano Letters.

"Every computer and phone has millions to billions of electronic transistors made from silicon, but this technology is reaching its physical limits where the silicon atoms get in the way of the current flow, limiting speed and causing heat," Shruti Nirantar, researcher at RMIT University, said in a news release.

"Our air channel transistor technology has the current flowing through air, so there are no collisions to slow it down and no resistance in the material to produce heat."

Over the last decade-plus, the power and efficiency of computer chips has roughly doubled every two years as engineers find new ways to squeeze more and more transistors onto silicon chips. But transistors are now smaller than the most minuscule viruses, and technologists say there is a limit to how much smaller they can get.

In other words, there is a wall or ceiling for silicon-based electronics, and engineers are already approaching it. Air-based nanochips could offer researchers access to a new paradigm in nano electronics.

"This technology simply takes a different pathway to the miniaturisation of a transistor in an effort to uphold Moore's Law for several more decades," Shruti said.

According to the new research, the proof-of-concept design avoids one of the problems with traditional solid channel transistors: too many atoms. Instead of using vacuum packing to make transistors less dense -- which would have added too much physical bulk to the technology -- researchers deployed a narrow air gap.

"The gap is only a few tens of nanometers, or 50,000 times smaller than the width of a human hair, but it's enough to fool electrons into thinking that they are travelling through a vacuum and re-create a virtual outer-space for electrons within the nanoscale air gap," researcher Sharath Sriram said.

Researchers think their device will be easily integratabtle with current electronic technologies.

"This is a step towards an exciting technology which aims to create something out of nothing to significantly increase speed of electronics and maintain pace of rapid technological progress," Sriram said.


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