First-ever X-ray attosecond experiment on liquids provides new insights into water’s molecular properties
Theorists explain how X-ray measurement freezes hydrogen motion, with implications on other areas of chemistry
Water molecules are special in many ways – their shape and the way their electrons are distributed means each H2O molecule has two electric poles. This polarity allows water to electrically attract to other water molecules and other similarly polar molecules. This attraction, called ‘hydrogen bonding’, and the structure among the molecules that the hydrogen bonds form is vital to understanding water’s unique behaviour and how it reacts chemically, including in processes essential to life. Scientists can monitor such structuring using X-ray emission spectroscopy (XES). XES is a method in which a molecule is exposed to X-rays and then releases X-rays of its own that transmit information about the motion of the molecule and about its chemical bonds.
In parallel, scientists have developed techniques using lasers to study phenomena beyond the capability of XES – a field called attosecond science, for which in 2023 the Nobel Prize in Physics was awarded. The Linda Young-led experimental team, which used the LCLS X-ray laser at SLAC National Accelerator Laboratory in the US, managed to use X-ray attosecond pulse pairs, with the pulses within the pair timed a few hundred attoseconds apart from one another, to find a signal in conflict with XES data, which have been interpreted as showing two structural motifs in water. For the first time attosecond X-ray laser pulses were used to investigate non-gaseous matter.
To explain their odd result, Young’s team turned to theoretical physicists who could calculate and model what had happened. Santra, the head of the theory group at the Center for Free Electron Laser Science (CFEL) at DESY, considered a hypothesis in the theory community that hydrogen atoms in the water could be the deciding factor. “When X-rays pass through water, the hydrogen atoms, which are very light, can start moving,” Santra says. “That motion could be what was picked up in the XES measurement, rather than two different structures being detected.”
Santra’s team produced a model to examine how the experiment progressed at the level of the electrons. In contrast to XES measurements, where X-rays would knock out a low-energy inner electron and a higher energy outer electron would replace it, causing the hydrogen atoms to move, the LCLS experiment led exactly to the reverse: causing an inner electron to move further out. The theoretical model of Santra’s team showed that this difference kept the hydrogen from moving, in addition to the attosecond timing being faster than any motion of the hydrogen. “In effect, this worked as a switch to ‘turn off’ the movement of the hydrogen atom,” says Swarnendu Bhattacharyya, one of the first authors on the paper and a postdoc in Santra’s group.
“In principle, we cannot rule two structures out. However, they do not correspond to the two features seen in the XES measurement,” says Santra. “The motion of the hydrogen atoms in the water molecule generates this effect.” Moreover, if such an effect provides a result in XES measurements that invites error, it could mean this fundamental tool in looking at the structure of molecules, might need to be re-evaluated. This would be particularly important for the future understanding of molecules rich in hydrogen – including, crucially, hydrocarbons, comprising almost all molecules found in living things, almost all fuels we use, and chemicals vital to industry and everyday life.
“This experiment opens the door to attosecond X-ray laser science,” says Santra. Until now, most attosecond science has taken place using optical lasers on gas samples. “Using attosecond science techniques with optical lasers, this result would not have been possible. Now this team has shown a way to adapt attosecond techniques to condensed matter with much brighter light, and it has already revealed something potentially significant about our understanding of matter – that with XES measurements we may not be getting the whole picture of matter as it exists in nature.”
DESY’s experience and techniques were crucial in this result and form a cornerstone towards the future Centre for Molecular Water Science (CMWS) that DESY is setting up. The experimental and theoretical teams for this result comprise scientists from Argonne National Laboratory, the University of Washington, Pacific Northwest National Laboratory, Washington State University, the University of Chicago, and SLAC National Accelerator Laboratory, all in the US; and DESY, Universität Hamburg, and the Hamburg Cluster of Excellence “CUI: Advanced Imaging of Matter,” all in Germany.
Original publication
Shuai Li, Lixin Lu, Swarnendu Bhattacharyya, Carolyn Pearce, Kai Li, Emily T. Nienhuis, Gilles Doumy, R.D. Schaller, S. Moeller, M.-F. Lin, G. Dakovski, D.J. Hoffman, D. Garratt, Kirk A. Larsen, J.D. Koralek, C.Y. Hampton, D. Cesar, Joseph Duris, Z. Zhang, Nicholas Sudar, James P. Cryan, A. Marinelli, Xiaosong Li, Ludger Inhester, Robin Santra, Linda Young; "Attosecond-pump attosecond-probe x-ray spectroscopy of liquid water"; Science, 2024-2-15
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Topic World Spectroscopy
Investigation with spectroscopy gives us unique insights into the composition and structure of materials. From UV-Vis spectroscopy to infrared and Raman spectroscopy to fluorescence and atomic absorption spectroscopy, spectroscopy offers us a wide range of analytical techniques to precisely characterize substances. Immerse yourself in the fascinating world of spectroscopy!
Topic World Spectroscopy
Investigation with spectroscopy gives us unique insights into the composition and structure of materials. From UV-Vis spectroscopy to infrared and Raman spectroscopy to fluorescence and atomic absorption spectroscopy, spectroscopy offers us a wide range of analytical techniques to precisely characterize substances. Immerse yourself in the fascinating world of spectroscopy!