MADISON, Wis. — Imagine pointing your smartphone at a salty snack you found at the back of your pantry and immediately knowing if its ingredients had turned rancid.
Devices called spectrometers can detect dangerous chemicals based on a unique “fingerprint” of absorbed and emitted light. But these light-splitting instruments have long been both bulky and expensive, preventing their use outside the lab.
Until now. Engineers at the University of Wisconsin-Madison have developed a spectrometer so small and simple that it could integrate with the camera of a typical cellphone without sacrificing accuracy.
“This is a compact, single-shot spectrometer that offers high resolution with low fabrication costs,” says Zhu Wang, who was among the team of electrical engineers that created the device.
The researchers published a description of the devices recently in the journal Nature Communications.
The team’s devices also have an advanced capability called hyperspectral imaging, which collects information about each individual pixel in an image order to identify materials or detect specific objects amidst a complicated background.
Hyperspectral sensing, for example, could be used to detect seams of valuable minerals within rock faces or to identify specific plants in a highly vegetated area.
Every element’s spectral fingerprint includes unique emitted or absorbed wavelengths of light — and the spectrometer’s ability to sense that light is what has enabled researchers to do everything from analyze the composition of unknown compounds to reveal the makeup of distant stars.
Spectrometers usually rely on prisms or gratings to split light emitted from an object into discrete bands — each corresponding to a different wavelength. A camera’s photodetector can capture and analyze those bands. The spectral fingerprint of the element sodium, for example, consists of two bands with wavelengths of 589 and 590 nanometers.
Human eyes see 590-nanometer wavelength light as a yellowish-orange shade. Shorter wavelengths correspond to blues and purples, whereas longer wavelengths appear red. Sunlight contains a complete rainbow mixed together, which we see as white.
To resolve the difference among a mixture of different colors, spectrometers usually must be relatively large with a long path length for light beams to travel and separate. Yet the team created tiny spectrometers, measuring just 200 micrometers on each side (roughly one-20th the area of a ballpoint pen tip) and delicate enough to lie directly on a sensor from a typical digital camera.
That small size was possible because the researchers based their device on specially designed materials that forced incoming light to bounce back and forth several times before reaching the sensor. Those internal reflections elongated the path along which light traveled without adding bulk, boosting the devices’ resolution.
And the devices performed hyperspectral imaging, resolving two distinct images (of the numbers 5 and 9) from a snapshot of an overlaid projection that combined the pair into something indistinguishable to the naked eye.
Now the team hopes to boost the device’s spectral resolution as well as the clarity and crispness of the images it captures. Those improvements could pave the way for even more enhanced sensors.
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Yu’s collaborators at UW-Madison included engineering Professor Mikhail Kats, Soongyu Yi, Ang Chen, Ming Zhou, Graham Joe and Alireza Shahsafi. Ken Xingze Wang of Huazhong University of Science and Technology and Ting Shan Luk, Anthony James, John Nogan and Willard Ross of Sandia National Laboratories contributed to the research.
This research was supported by the National Science Foundation and the Defense Advanced Research Projects Agency CAREER Award and DARPA Young Faculty Award (YFA) supported the research.
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