Select your localized edition:

Close ×

More Ways to Connect

Discover one of our 28 local entrepreneurial communities »

Be the first to know as we launch in new countries and markets around the globe.

Interested in bringing MIT Technology Review to your local market?

MIT Technology ReviewMIT Technology Review - logo

 

Unsupported browser: Your browser does not meet modern web standards. See how it scores »

Instead of silicon, InVisage uses a layer of quantum dots as a light collector. Quantum dots are a relatively new technology that have only recently found their way into products. QD Vision, a startup that spun out of an MIT lab, is currently using quantum dots to improve the color of LED lighting. Quantum dots can also be used to improve the efficiency of liquid crystal displays.

In the case of QuantumFilm, a liquid layer of quantum dots consisting of lead and sulfide is added to the top of an image sensor, above the electronics and silicon, but below a color filter. Light passes through the color filter and is absorbed by the quantum dots, creating a negatively charged electron, and the other a positively charged “hole.” According to Sargent, the quantum dot layer is about twice as efficient as silicon, registering almost 100 percent of the photons. An electric field below the quantum dot layer separates the electrons from the holes, sweeping the electrons away to the circuitry below, where they are measured as an electrical signal.

The major consideration for adding a new layer or device into a product is to make sure it can be manufactured cheaply, says Seth Coe-Sullivan, chief technology officer at QD Vision. Integrating quantum dots into silicon manufacturing processes is where InVisage “is in uncharted territory,” Coe-Sullivan says.

InVisage is modifying a process already used to make the chips by applying a photoresist to a silicon wafer, to etch features into the silicon. After all the transistors have been made and metal interconnects have been laid down, a small amount of liquid containing quantum dots is spun onto the wafer in the same way as the photoresist. The solution dries and leaves behind a layer of quantum dots about a micron thick.

It’s a difficult task to completely overhaul the silicon sensor used in cell phone cameras because it’s a cost-sensitive device. While quantum dots, when prepared appropriately, have the ability to filter light, manufacturers are likely to keep the original color filters on the sensors, at least in the beginning. However, if QuantumFilm takes off, manufacturers could get rid of the filters completely, says Sargent.

Peter Catrysse, a researcher working on nanophotonic materials at Stanford University agrees that it’s good to start with small changes to the sensor design and not try to change everything at once. “While that might not deliver the greatest promise that quantum dot-based photodetectors have to offer, it may get their technology in the door,” he says.

InVisage, which has attracted more than $30 million in funding since it was founded in 2006, has partnered with Taiwan Semiconductor Manufacturing Company to integrate the quantum dots into the silicon chip-making process. The company expects to sample their camera sensors in 10 months, and the first quantum dot cameras could be on the market by the end of 2011.

6 comments. Share your thoughts »

Credit: InVisage

Tagged: Communications, imaging, electronics, camera, photonics, quantum dots

Reprints and Permissions | Send feedback to the editor

From the Archives

Close

Introducing MIT Technology Review Insider.

Already a Magazine subscriber?

You're automatically an Insider. It's easy to activate or upgrade your account.

Activate Your Account

Become an Insider

It's the new way to subscribe. Get even more of the tech news, research, and discoveries you crave.

Sign Up

Learn More

Find out why MIT Technology Review Insider is for you and explore your options.

Show Me