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Colour-changing magnifying glass gives clear view of infrared light:
Detecting light beyond the visible red range of our eyes is hard to do, because infrared light carries so little energy compared to ambient heat at room temperature. This obscures infrared light unless specialised detectors are chilled to very low temperatures, which is both expensive and energy-intensive.
Now researchers led by the University of Cambridge have demonstrated a new concept in detecting infrared light, showing how to convert it into visible light, which is easily detected.
In collaboration with colleagues from the UK, Spain and Belgium, the team used a single layer of molecules to absorb the mid-infrared light inside their vibrating chemical bonds. These shaking molecules can donate their energy to visible light that they encounter, ‘upconverting’ it to emissions closer to the blue end of the spectrum, which can then be detected by modern visible-light cameras.
The results, reported in the journal Science, open up new low-cost ways to sense contaminants, track cancers, check gas mixtures, and remotely sense the outer universe.
The challenge faced by the researchers was to make sure the quaking molecules met the visible light quickly enough. “This meant we had to trap light really tightly around the molecules, by squeezing it into crevices surrounded by gold,” said first author Angelos Xomalis from Cambridge’s Cavendish Laboratory.
The researchers devised a way to sandwich single molecular layers between a mirror and tiny chunks of gold, only possible with ‘meta-materials’ that can twist and squeeze light into volumes a billion times smaller than a human hair.
“Trapping these different colours of light at the same time was hard, but we wanted to find a way that wouldn’t be expensive and could easily produce practical devices,” said co-author Dr Rohit Chikkaraddy from the Cavendish Laboratory, who devised the experiments based on his simulations of light in these building blocks.
Journal Reference:
Angelos Xomalis, Xuezhi Zheng, Rohit Chikkaraddy, et al. Detecting mid-infrared light by molecular frequency upconversion in dual-wavelength nanoantennas, Science 2021; 374 (6572): 1268 (DOI: 10.1126/science.abk2593)
(Score: 4, Informative) by ChrisMaple on Friday December 03 2021, @01:06AM (2 children)
In my understanding, 10 micron is far infrared, not middle.
This sounds like a very nice piece of science with practical applications.
(Score: 2) by FatPhil on Friday December 03 2021, @08:16AM (1 child)
Great minds discuss ideas; average minds discuss events; small minds discuss people; the smallest discuss themselves
(Score: 0) by Anonymous Coward on Monday December 06 2021, @08:49PM
So will the sensor companies that are trying to get buy-in from self-driving car companies--a potentially huge market, IF you can break in. But the car companies are tough customers with high reliability specs in addition to low prices.