Mapping out a transient atom

An international team from Germany, Sweden, Russia and the USA, led by scientists from European XFEL, has published the results of an experiment that could provide a blueprint for the analysis of transitions states in atoms and molecules. This would open up new opportunities to gain insights into important processes such as photocatalysis, elementary steps in photosynthesis and radiation damage.

It was the very first user experiment carried out at European XFEL’s Small Quantum System (SQS) instrument. The scientists used high-resolution electron spectroscopy to capture a snapshot of the short-lived transient state produced when X-rays punch a hole in the very core of the atomic electron cloud. The results of the study, which was carried out on neon atoms, are the starting point for the analysis of transient states and have been published in Physical Review X.

The extremely short-lived transient state of core-exited neon lasts for just 2.4 femtoseconds. To put a femtosecond in context: a femtosecond is to a second as a second is to about 31.71 million years. “The European XFEL allows us to use a high number of laser pulses per second and high pulse energy. This means we can bring a very high number of photons to the sample, which is crucial to probe such transient atomic states,” explains Tommaso Mazza, the lead author of the paper.

“We used intense X-ray pulses to first remove the electrons from the inner shell, or core, of a neon atom and then used a second photon from the same X-ray pulse to map out the ‘hollow’ atom,” says Mazza. “This is the first time scientists are able to obtain information of the electronic structure of this core-hole transient state by X-ray induced electron spectroscopy, and, more precisely, by measuring the energy of the electrons emitted after the excitation by the second photon while smoothly changing the wavelength of the X-ray pulses,” he adds.

Leading Scientist at SQS Michael Meyer underlines that the results of this paper along with a paper recently published in Science show the outstanding possibility to efficiently control and probe excitations of specific electronic subshells at the SQS instrument. “We can enable atomic or element specific excitations in molecular targets and independently investigate for each atom the influence on the photon-induced molecular dynamics,” he says. Targeting a specific atom in a molecule allows scientists to gain deeper understanding of the behavior of individual building blocks in the molecular assembly under intense irradiation.

About European XFEL

The European XFEL in the Hamburg area is an international research facility of superlatives: 27,000 X-ray flashes per second and a brilliance that is a billion times higher than that of the best conventional X-ray sources open up completely new opportunities for science. Research groups from around the world are able to map the atomic details of viruses, decipher the molecular composition of cells, take three-dimensional “photos” of the nanoworld, “film” chemical reactions, and study processes such as those occurring deep inside planets. The operation of the facility is entrusted to European XFEL, a non-profit company that cooperates closely with its main shareholder, the research centre DESY, and other organisations worldwide. European XFEL has a workforce of more than 450 employees and started user operation September 2017. At present, 12 countries have signed the European XFEL convention: Denmark, France, Germany, Hungary, Italy, Poland, Russia, Slovakia, Spain, Sweden, Switzerland, and the United Kingdom. For more information on European XFEL go to www.xfel.eu.

Contact:
Bernd Ebeling
Tel. +49 40 8998 6921
bernd.ebeling@xfel.eu

Originalpublikation:

https://link.aps.org/doi/10.1103/PhysRevX.10.041056

Weitere Informationen:

https://www.xfel.eu/news_and_events/news/index_eng.html?openDirectAnchor=1844&am… Picture