New technique for exploring structural dynamics of nanoworld
Combining Two Techniques on One Benchtop
Integrating the two techniques proved challenging. Because electrons repel each other, there are only so many electrons that can be packed into one pulse. As you shorten each pulse to increase the time resolution, each pulse then contains fewer electrons, and the chance of interaction between the probing electrons and the core electrons decreases. Particularly at the high energy levels required to excite the deep core electrons (1st and 2nd electron shells), "the signal from many electron packets must be integrated over a long time," explained van der Veen.
The researchers tested their technique on graphite thin-films, demonstrating that laser excitation causes the in-plane carbon-carbon bonds in the structure to expand and the π-π* energy gap to shrink on the picosecond (one trillionth of a second) time scale.
Core-loss spectroscopy is in some ways similar to X-ray absorption spectroscopy, but it has a few critical advantages. "Using X-rays, the study of individual nano-objects and the in situ atomic-scale imaging of materials remains quite challenging. In this respect, ultrafast core-loss spectroscopy in electron microscopy provides a huge advantage. Imaging, diffraction and spectroscopy are all combined within the same table-top setup; complementary information about the same sample can readily be obtained," said van der Veen.
The ability to visualize the ultrafast dynamics of individual atoms has broad applications across scientific disciplines, from materials science to biology. The researchers hope that future developments in "pulsed electron sources and detection methods" will enable their technique to be used in more advanced experiments.
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