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New display tech could bring 'drastically' higher resolution to your phone and TV

Researchers at the University of Central Florida have developed a new color-changing surface tunable through electrical voltage -- a breakthrough that could lead to three times the resolution for televisions, smartphones, and other devices.

Video screens are made up of hundreds of thousands of pixels that display different colors to form the images. With current technology, each of these pixels contains three subpixels: one red, one green, one blue.

But a scientific advancement in a lab at UCF's NanoScience Technology Center may eventually make that model a thing of the past. Assistant Professor Debashis Chanda and physics doctoral student Daniel Franklin have come up with a way to tune the color of these subpixels. By applying differing voltages, they are able to change the color of individual subpixels to red, green, or blue -- the RGB scale -- or gradations in between.

"We can make a red subpixel go to blue, for instance," Chanda said. "In other displays, that is not possible because they need three static color filters to show the full RGB color. We don't need that now; a single subpixel-less pixel can be tuned across a given color gamut."

In the liquid crystal-plasmonic device, ambient white light passes through a polarizer, substrate, and liquid crystal (LC) layer to interact with a continuous aluminum nanostructure. The plasmonic surface exhibits a polarization dependence from surface roughness, absorbing light and reflecting the rest. The wavelength of this absorption depends on the LC orientation near the surface and the polarization of incident light. By applying a field across the cell, the orientation of the bulk LC and interfacial LC can be changed, resulting in red, green, and blue reflection.





The research was reported this month in the academic journal Nature Communications.

Aside from the inherent value of an improved design for the pixel-based displays that are ubiquitous in today's world, their findings have other advantages.

By eliminating the three static subpixels that currently make up every pixel, the size of individual pixels can be reduced by three. Three times as many pixels means three times the resolution. That would have major implications for not only TVs and other general displays, but augmented reality and virtual reality headsets that need very high resolution because they're so close to the eye.

"A subpixel-less display can increase resolution drastically," Franklin said. "You can have a much smaller area that can do all three."

And because there would no longer be a need to turn off some subpixels to display a solid color -- there would be no more subpixels, after all -- the brightness of screens could be much greater.

Franklin and Chanda built on earlier research that demonstrated the world's first proof-of-concept display utilizing the plasmonic phenomenon (Nature Communications, Vol. 6, pp. 7337, 2015).

They've created an embossed nanostructure surface resembling an egg crate, covered with a skin of reflective aluminum. However, they needed several variations of this nanostructure to achieve the full range of colors. In their latest advance, they found that modifying the roughness of the surface allowed a full range of colors to be achieved with a single nanostructure.

The nanostructure surface can be easily integrated with existing display technology, so the underlying hardware wouldn't need to be replaced or re-engineered.

"It allows you to leverage all the pre-existing decades of LCD technology. We don't have to change all of the engineering that went into making that," Franklin said.

University of Central Florida Assistant Professor Debashis Chanda and physics PhD student Daniel Franklin have made a breakthrough that could produce much higher resolution for TVs, smartphones, and other video screens.





The researchers are now taking steps to scale up their displays in preparation for bringing the technology to the private sector.

The research team also includes Professor Shin-Tson Wu of CREOL, The College of Optics & Photonics at UCF, and Russell Frank, an undergraduate researcher in Chanda's lab.

Journal Reference:
1. Daniel Franklin, Russell Frank, Shin-Tson Wu, Debashis Chanda. Actively addressed single pixel full-color plasmonic display. Nature Communications, 2017; 8: 15209 DOI: 10.1038/ncomms15209

Source: University of Central Florida

Published August 2017

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