Quantum Dots for Cheaper IR-Cameras

Photos taken by researchers testing a new method to make an infrared camera that could be much less expensive to manufacture. (Source: X. Tang et al.)

There’s an entire world our eyes miss, hidden in the ranges of light wavelengths that human eyes can’t see. But infrared cameras can pick up the secret light emitted as plants photo­synthesize, as cool stars burn and batteries get hot. They can see through smoke and fog and plastic. But infrared cameras are much more expensive than visible-light ones; the energy of infrared light is smaller than visible light, making it harder to capture. A new break­through by scientists with the Univer­sity of Chicago, however, may one day lead to much more cost-effective infrared cameras – which in turn could enable infrared cameras for common consumer electronics like phones, as well as sensors to help auto­nomous cars see their surroundings more accurately.

“Traditional methods to make infrared cameras are very expensive, both in materials and time, but this method is much faster and offers excellent performance,” said post­doctoral researcher Xin Tang. “That’s why we’re so excited about the potential commercial impact,” said his colleague Philippe Guyot-Sionnest, a professor of physics and chemistry. Today’s infrared cameras are made by suc­cessively laying down multiple layers of semi­conductors – a tricky and error-prone process that makes them too expensive to go into most consumer electronics.

Guyot-Sionnest’s lab instead turned to quantum dots. At that scale they have odd properties that change depending on their size, which scientists can control by tuning the particle to the right size. In this case, quantum dots can be tuned to pick up wave­lengths of infrared light. This tuna­bility is important for cameras, because they need to pick up different parts of the infrared spectrum. “Collecting multiple wavelengths within the infrared gives you more spectral information – it’s like adding color to black-and-white TV,” Tang explained. “Short-wave gives you textural and chemical compo­sition information; mid-wave gives you temperature.”

They tweaked the quantum dots so that they had a formula to detect short-wave infrared and one for mid-wave infrared. Then they laid both together on top of a silicon wafer. The resulting camera performs extremely well and is much easier to produce. “It’s a very simple process,” Tang said. “You take a beaker, inject a solution, inject a second solution, wait five to 10 minutes, and you have a new solution that can be easily fabricated into a functional device.”

There are many potential uses for inex­pensive infrared cameras, the scientists said, including auto­nomous vehicles, which rely on sensors to scan the road and surroundings. Infrared can detect heat signatures from living beings and see through fog or haze, so car engineers would love to include them, but the cost is prohi­bitive.

They would come in handy for scientists, too. “If I wanted to buy an infrared detector for my labora­tory today, it would cost me $25,000 or more,” Guyot-Sionnest said. “But they would be very useful in many dis­ciplines. For example, proteins give off signals in infrared, which a biologist would love to easily track.” (Source: U. Chicago)

Reference: X. Tang et al.: Dual-band infrared imaging using stacked colloidal quantum dot photodiodes, Nat. Phot., online 25 February 2019; DOI: 10.1038/s41566-019-0362-1

Link: James Franck Institute, University of Chicago, Chicago, USA

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