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Carl Taussig unfurls a roll of silvery plastic patterned with arrays of small iridescent squares, each a few centimeters across. The plastic in his hands, along with the scraps and scrolls of the material scattered on benchtops and desks in the rooms of Hewlett-Packard Labs in Palo Alto, CA, may look like silver wrapping paper, but each square contains thousands of silicon transistors. The transistors can switch pixels in displays on and off as fast as those in conventional flat-screen monitors and televisions, but they’re far cheaper to fabricate and more resilient.

In today’s displays, whether they’re flat-panel TVs or iPads, the electronics that control the pixels are made of amorphous silicon on glass. Taussig’s goal is to replace these heavy, fragile, expensive displays with lightweight, rugged, inexpensive ones made on plastic–without compromising performance. He is using high-volume roll-to-roll mechanics, the type of high-speed manufacturing process used in newspaper production, to make high-performance transistor arrays on the 33-centimeter-wide plastic rolls. HP researchers are now engineering a process for a planned pilot plant, where the company will produce the arrays at volumes of about 46,500 square meters a year through a partnership with Phicot, a manufacturer of thin-film electronics based in Ames, IA.

The idea is to combine these transistor arrays with flexible “frontplanes”–the part of a display that creates the images and that the transistors control. “Our goal is to make displays at a cost of $10 per square foot,” Taussig says. That’s about a 10th the price of today’s displays. Silicon-on-plastic displays might be used in laptops, or a few thin sheets might be stuffed into briefcases, replacing printouts and pads of paper. Taussig also imagines “ginormous displays” pasted to walls to show videos and ads.

HP may not be the first company to market with a plastic display–Plastic Logic, which plans to release an e-reader soon, is likely to earn that distinction. But Plastic Logic’s display isn’t flexible–the plastic frontplanes and backplanes are protected by a rigid case. It also doesn’t use silicon; it uses lower-performance organic transistors that aren’t fast enough for video. HP hopes to gain an edge, ­Taussig says, by lowering the cost of the display while producing speedy, video-capable transistors.

Part of the reason silicon-on-plastic displays haven’t been produced before is that it’s difficult to deposit high-quality silicon at temperatures low enough to avoid melting the plastic. Hewlett-Packard ‘s partner, Phicot, has managed to solve that problem. HP has addressed another challenge: unlike glass, which provides a mechanically stable surface, plastic tends to distort. By finding a way to make nanoscale features on plastic, HP is opening the way to the large volumes and low costs that Taussig has in mind.

On a Roll

The key to forming nanoscale electronics on distortion-prone plastic is a process called self-aligned imprint lithography, which Taussig’s team invented in 2001, and which his group first applied to displays in 2006. Thin-film transistors have several layers, and in conventional manufacturing, the materials in each layer are deposited separately. After each layer is deposited, it’s carved into precise patterns before the next layer is added. This process requires careful alignment of the photolithographic masks used to outline each pattern. ­Taussig’s process, on the other hand, uses a ­single, three-­dimensional template to pattern all the layers, eliminating the need to align different masks. “It’s immune to distortion, which is the biggest challenge when making electronics roll-to-roll,” Taussig says.

Researcher Albert Jeans shows off the starting material: a roll of plastic film coated with several thin layers of metal, amorphous silicon, and other materials needed to make the electronic circuits. To create the three-dimensional template, he loads the roll onto a spindle and threads it into a machine. The film moves through the machine, and a stationary blade spreads a uniform coating of liquid polymer over it. A stamp creates intricate impressions in the polymer coating, and these are instantly frozen in place by an ultraviolet light, which solidifies the polymer.

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Credit: Jen Siska
Video by Katherine Bourzac, Edited by Brittany Sauser

Tagged: Computing, Materials

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