A novel technique with potential applications for fields such as droplet chemistry and photochemistry has been demonstrated by an Osaka Metropolitan University-led research group.
Credit: Osaka Metropolitan University
A novel technique with potential applications for fields such as droplet chemistry and photochemistry has been demonstrated by an Osaka Metropolitan University-led research group.
Professor Yasuyuki Tsuboi of the Graduate School of Science and the team investigated Förster resonance energy transfer (FRET), a phenomenon seen in photosynthesis and other natural processes where a donor molecule in an excited state transfers energy to an acceptor molecule.
Using dyes to mark the donor and acceptor molecules, the team set out to see if FRET could be controlled by the intensity of an optical force, in this case a laser beam. By focusing a laser beam on an isolated polymer droplet, the team showed that increased intensity accelerated the energy transfer, made visible by the polymer changing color due to the dyes mixing.
Fluorescence could also be controlled just by adjusting the laser intensity without touching the sample, offering a novel non-contact approach.
“Although this research is still at a basic stage, it may provide new options for a variety of future FRET research applications,” Professor Tsuboi explained. “We believe that extending this to quantum dots as well as new polymer systems and fluorescent molecules is the next challenge.”
The findings were published in Advanced Optical Materials.
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Journal
Advanced Optical Materials
DOI
10.1002/adom.202400302
Method of Research
Experimental study
Subject of Research
Not applicable
Article Title
Förster Resonance Energy Transfer Control by Means of an Optical Force
Article Publication Date
30-Apr-2024
COI Statement
The authors declare no conflict of interest.