Go to:
Previous Item
Current News
Next Item

The following is an unedited press release, shown as received from the company represented. We've elected to present selected releases without editorial comment, as a way to provide our readers more information without further overtaxing our limited editorial resources. To avoid any possible confusion or conflict of interest, the Imaging Resource will always clearly distinguish between company-provided press releases and our own editorial views and content.

University of Toronto's Rogers Department of Electrical Engineering logo. Click here to visit the Rogers Department of Electrical Engineering website! PRESS RELEASE: Light sensor breakthrough could enhance digital cameras


TORONTO, ON - New research by a team of U of T scientists could lead to substantial advancements in the performance of a variety of electronic devices including digital cameras.

Researchers created a light sensor - like a pixel in a digital camera - that benefits from a phenomenon known as multi-exciton generation (MEG). Until now, no group had collected an electrical current from a device that takes advantage of MEG.

"Digital cameras are now universal but they suffer from a major limitation: they take poor pictures under dim light. One reason for this is that the image sensor chips inside cameras collect, at most, one electron's worth of current for every photon (particle of light) that strikes the pixel," said Professor Ted Sargent of electrical and computer engineering. "Instead generating multiple excitons per photon could ultimately lead to better low-light pictures."

In solar cells and digital cameras, particles of light - known as photons - are absorbed in a semiconductor, such a silicon, and generate excited electrons, known as excitons. The semiconductor chip then measures a current that flows as a result. Normally, each photon is converted into at most one exciton. This lowers the efficiency of solar cells and it limits the sensitivity of digital cameras. When a scene is dimly lit, small portable cameras like those in laptops suffer from noise and grainy images as a result of the small number excitons.

"Multi-exciton generation breaks the conventional rules that bind traditional semiconductor devices," Sargent said. "This finding shows that it's more than a fascinating concept: the tangible benefits of multiple excitons can be seen in a light sensor's measured current."

The research was supported by grants from King Abdullah University of Science and Technology, Natural Sciences and Engineering Research Council of Canada, Canada Research Chairs, Canada Foundation for Innovation and Ontario Innovation Trust.


(First posted on Thursday, June 18, 2009 at 16:41 EDT)

Go to:
Previous Item
Current News
Next Item