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Paint-on Semiconductor Beats Traditional Chips

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TORONTO, July 18, 2006 -- Researchers have created a semiconductor device that outperforms conventional chips -- simply by painting a liquid onto a piece of glass.

The finding by University of Toronto (U of T) researchers represents the first time a so-called “wet” semiconductor device has bested traditional, more costly grown-crystal semiconductor devices, the researcher said. Their work is reported in the July 13 issue of the journal Nature.

“Traditional ways of making computer chips, fiber-optic lasers, digital camera image sensors -- the building blocks of the information age -- are costly in time, money and energy,” said professor Ted Sargent of the Edward S. Rogers Sr. Department of Electrical and Computer Engineering and leader of the research group.

Conventional semiconductors have produced spectacular results -- the personal computer, the Internet, digital photography -- but they rely on growing atomically-perfect crystals at 1000 °C and above, he said. The Toronto team instead cooked up semiconductor particles in a flask containing extra-pure oleic acid, the main ingredient in olive oil. The particles are just a few nanometers (one billionth of a meter) across.

The team then placed a drop of solution on a glass slide patterned with gold electrodes and forced the drop to spread out into a smooth, continuous semiconductor film using a process called spin-coating. They then gave their film a two-hour bath in methanol. Once the solvent evaporated, it left an 800-nm-thick layer of the light-sensitive nanoparticles.

At room temperature, the paint-on photodetectors were about 10 times more sensitive to infrared rays than the sensors that are currently used in military night-vision and biomedical imaging. “These are exquisitely sensitive detectors of light,” said Sargent, who holds a Canada Research Chair in Nanotechnology. “It’s now clear that solution-processed electronics can combine outstanding performance with low cost.”

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The U of T development could be of critical importance to both research and industry, according to John D. Joannopoulos, a physics professor at the Massachusetts Institute of Technology. “The ability to realize low-cost, paintable, high-performance designer semiconductors for use as short-wavelength infrared detectors and emitters is of enormous value for a wide range of communications, imaging and monitoring applications,” said Joannopoulos, who is also director of the Institute for Soldier Nanotechnologies at MIT.

“The key to our success was controlled engineering at the nanometer-length scale: tailoring colloidal nanocrystal size and surfaces to achieve exceptional device performance,” said lead author Gerasimos Konstantatos, a U of T doctoral researcher. “With this finding, we now know that simple, convenient, low-cost wet chemistry can produce devices with performance that is superior compared to that of conventional grown-crystal devices.”

The research was supported by the Natural Sciences and Engineering Research Council of Canada's Idea to Innovation Program, the Canada Foundation for Innovation and the Province of Ontario through the Ontario Centres of Excellence and the Canada Research Chairs program. For more information, visit: www.news.utoronto.ca

Published: July 2006
Glossary
infrared
Infrared (IR) refers to the region of the electromagnetic spectrum with wavelengths longer than those of visible light, but shorter than those of microwaves. The infrared spectrum spans wavelengths roughly between 700 nanometers (nm) and 1 millimeter (mm). It is divided into three main subcategories: Near-infrared (NIR): Wavelengths from approximately 700 nm to 1.4 micrometers (µm). Near-infrared light is often used in telecommunications, as well as in various imaging and sensing...
nanometer
A unit of length in the metric system equal to 10-9 meters. It formerly was called a millimicron.
photodetector
A photodetector, also known as a photosensor or photodiode, is a device that detects and converts light into an electrical signal. Photodetectors are widely used in various applications, ranging from simple light sensing to more complex tasks such as imaging and communication. Key features and principles of photodetectors include: Light sensing: The primary function of a photodetector is to sense or detect light. When photons (particles of light) strike the active area of the photodetector,...
Basic SciencecamerasCommunicationsdefensefiber-optic lasersfilmimage sensorsImaginginfrarednanocrystalnanometerNews & Featurespaint-onphotodetectorsemiconductorsSensors & Detectorsspin-coatingTed SargentUniversity of Torontowet semiconductor

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