World’s fastest camera can capture 156.3 trillion frames per second
The cutting-edge imaging device is fast enough to capture phenomena like transient absorption in a semiconductor and ultrafast demagnetization of a metal alloy in a single shot
From the Techspot website:
Researchers at the National Institute of Scientific Research (INRS) in Quebec have developed an ultrafast camera capable of providing full-sequence encoding rates of up to 156.3 THz to individual pixels, which works out to 156.2 trillion frames per second. Dubbed SCARF, which is short for swept-coded aperture real-time femtophotography, the cutting-edge imaging device is fast enough to capture phenomena like transient absorption in a semiconductor and ultrafast demagnetization of a metal alloy in a single shot.
INRS believes the new imaging hardware will help expand knowledge boundaries across a range of fields including biology, chemistry, materials science, physics, and engineering. It will be especially useful when observing non-repeatable or hard-to-reproduce phenomena like shock wave mechanics in living cells, the researchers said.
Professor Jinyang Liang is a pioneer in the ultrafast imaging space. In 2018, he developed the T-CUP (trillion-frame-per-second compressed ultrafast photography). Based on passive femtosecond imagining, that system was capable of capturing 10 trillion frames per second.
Up to that point, fast camera systems mostly captured frames sequentially, one by one, then stitched them together to create the scene.
T-CUP was groundbreaking, but not without shortcomings. Miguel Marquez, a member of Jinyang’s team, said systems based on compressed ultrafast photography have to contend with degraded data quality. What’s more, they also have to trade the sequence depth of the field of view. “These limitations are attributable to the operating principle, which requires simultaneously shearing the scene and the coded aperture,” Marquez noted.
As INRS highlights, SCARF overcomes these challenges thanks to its imaging modality, which enables “fast sweeping of a static coded aperture while not shearing the ultrafast phenomenon.”
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