Until recently, molecular movements in gases and solids could be visualized by high-speed electron cameras by scattering a beam of electrons off a sample. Researchers have now adapted this technique, ultrafast electron diffraction, to molecules in liquid samples.
As reported by the Department of Energy’s SLAC National Accelerator Laboratory, Stanford University and the University of Nebraska-Lincoln (UNL), the method creates 100-nm thick liquid jets, approx. 1,000 times thinner than the width of human hair, which enables researchers to capture clear diffraction patterns from electrons. This method could potentially be used to explore light-driven processes such as vision, catalysis, photosynthesis and DNA damage caused by UV rays. The results of the study were published in Structural Dynamics in March 2020.
According to SLAC, the fact that most important biological and chemical processes, especially the conversion of light into energy, happen in a solution is what makes this technique paramount to research. The miniscule wavelengths of these high-energy electrons can capture high-resolution snapshots, offering insight into processes such as proton transfer and hydrogen bond breaking that are difficult to study with other methods.
Published by Cosmetics &Toiletries, April 16, 2020
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