Imaging Valence Electron Rearrangement in a Chemical Reaction Using Hard X-Ray Scattering

Ian Gabalski; Alice Green; Philipp Lenzen; Felix Allum; Matthew Bain; Surjendu Bhattacharyya; Mathew A. Britton; Elio G. Champenois; Xinxin Cheng; James P. Cryan; Taran Driver; Ruaridh Forbes; Douglas Garratt; Aaron M. Ghrist; Martin Graßl; Matthias F. Kling; Kirk A. Larsen; Mengning Liang; Ming Fu Lin; Yusong Liu; Michael P. Minitti; Silke Nelson; Joseph S. Robinson; Philip H. Bucksbaum; Thomas J.A. Wolf; Nanna H. List; James M. Glownia

doi:10.1103/53h3-vykl

Imaging Valence Electron Rearrangement in a Chemical Reaction Using Hard X-Ray Scattering

Ian Gabalski, Alice Green, Philipp Lenzen, Felix Allum, Matthew Bain, Surjendu Bhattacharyya, Mathew A. Britton, Elio G. Champenois, Xinxin Cheng, James P. Cryan, Taran Driver, Ruaridh Forbes, Douglas Garratt, Aaron M. Ghrist, Martin Graßl, Matthias F. Kling, Kirk A. Larsen, Mengning Liang, Ming Fu Lin, Yusong LiuMichael P. Minitti, Silke Nelson, Joseph S. Robinson, Philip H. Bucksbaum, Thomas J.A. Wolf, Nanna H. List, James M. Glownia

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Abstract

We have observed the signatures of valence electron rearrangement in photoexcited ammonia using ultrafast hard x-ray scattering. Time-resolved x-ray scattering is a powerful tool for imaging structural dynamics in molecules because of the strong scattering from the core electrons localized near each nucleus. Such core-electron contributions generally dominate the differential scattering signal, masking any signatures of rearrangement in the chemically important valence electrons. Ammonia represents an exception to the typically high core-to-valence electron ratio. We measured 9.8 keV x-ray scattering from gas-phase deuterated ammonia following photoexcitation via a 200 nm pump pulse to the 3s Rydberg state. We observed changes in the recorded scattering patterns due to the initial photoexcitation and subsequent deuterium dissociation. Ab initio calculations confirm that the observed signal is sensitive to the rearrangement of the single photoexcited valence electron as well as the interplay between adiabatic and nonadiabatic dissociation channels. The use of ultrafast hard x-ray scattering to image the structural rearrangement of single valence electrons constitutes an important advance in tracking valence electronic structure in photoexcited atoms and molecules.

Original language	English
Pages (from-to)	83001
Number of pages	1
Journal	Physical Review Letters
Volume	135
Issue number	8
Early online date	20 Aug 2025
DOIs	https://doi.org/10.1103/53h3-vykl
Publication status	E-pub ahead of print - 20 Aug 2025

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https://journals.aps.org/prl/abstract/10.1103/53h3-vykl

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Gabalski, I., Green, A., Lenzen, P., Allum, F., Bain, M., Bhattacharyya, S., Britton, M. A., Champenois, E. G., Cheng, X., Cryan, J. P., Driver, T., Forbes, R., Garratt, D., Ghrist, A. M., Graßl, M., Kling, M. F., Larsen, K. A., Liang, M., Lin, M. F., ... Glownia, J. M. (2025). Imaging Valence Electron Rearrangement in a Chemical Reaction Using Hard X-Ray Scattering. Physical Review Letters, 135(8), 83001. Advance online publication. https://doi.org/10.1103/53h3-vykl

@article{56139699e99f4dab92f99d938bcc6a4f,

title = "Imaging Valence Electron Rearrangement in a Chemical Reaction Using Hard X-Ray Scattering",

abstract = "We have observed the signatures of valence electron rearrangement in photoexcited ammonia using ultrafast hard x-ray scattering. Time-resolved x-ray scattering is a powerful tool for imaging structural dynamics in molecules because of the strong scattering from the core electrons localized near each nucleus. Such core-electron contributions generally dominate the differential scattering signal, masking any signatures of rearrangement in the chemically important valence electrons. Ammonia represents an exception to the typically high core-to-valence electron ratio. We measured 9.8 keV x-ray scattering from gas-phase deuterated ammonia following photoexcitation via a 200 nm pump pulse to the 3s Rydberg state. We observed changes in the recorded scattering patterns due to the initial photoexcitation and subsequent deuterium dissociation. Ab initio calculations confirm that the observed signal is sensitive to the rearrangement of the single photoexcited valence electron as well as the interplay between adiabatic and nonadiabatic dissociation channels. The use of ultrafast hard x-ray scattering to image the structural rearrangement of single valence electrons constitutes an important advance in tracking valence electronic structure in photoexcited atoms and molecules.",

author = "Ian Gabalski and Alice Green and Philipp Lenzen and Felix Allum and Matthew Bain and Surjendu Bhattacharyya and Britton, \{Mathew A.\} and Champenois, \{Elio G.\} and Xinxin Cheng and Cryan, \{James P.\} and Taran Driver and Ruaridh Forbes and Douglas Garratt and Ghrist, \{Aaron M.\} and Martin Gra{\ss}l and Kling, \{Matthias F.\} and Larsen, \{Kirk A.\} and Mengning Liang and Lin, \{Ming Fu\} and Yusong Liu and Minitti, \{Michael P.\} and Silke Nelson and Robinson, \{Joseph S.\} and Bucksbaum, \{Philip H.\} and Wolf, \{Thomas J.A.\} and List, \{Nanna H.\} and Glownia, \{James M.\}",

year = "2025",

month = aug,

day = "20",

doi = "10.1103/53h3-vykl",

language = "English",

volume = "135",

pages = "83001",

journal = "Physical Review Letters",

issn = "0031-9007",

publisher = "American Physical Society",

number = "8",

}

Gabalski, I, Green, A, Lenzen, P, Allum, F, Bain, M, Bhattacharyya, S, Britton, MA, Champenois, EG, Cheng, X, Cryan, JP, Driver, T, Forbes, R, Garratt, D, Ghrist, AM, Graßl, M, Kling, MF, Larsen, KA, Liang, M, Lin, MF, Liu, Y, Minitti, MP, Nelson, S, Robinson, JS, Bucksbaum, PH, Wolf, TJA, List, NH & Glownia, JM 2025, 'Imaging Valence Electron Rearrangement in a Chemical Reaction Using Hard X-Ray Scattering', Physical Review Letters, vol. 135, no. 8, pp. 83001. https://doi.org/10.1103/53h3-vykl

TY - JOUR

T1 - Imaging Valence Electron Rearrangement in a Chemical Reaction Using Hard X-Ray Scattering

AU - Gabalski, Ian

AU - Green, Alice

AU - Lenzen, Philipp

AU - Allum, Felix

AU - Bain, Matthew

AU - Bhattacharyya, Surjendu

AU - Britton, Mathew A.

AU - Champenois, Elio G.

AU - Cheng, Xinxin

AU - Cryan, James P.

AU - Driver, Taran

AU - Forbes, Ruaridh

AU - Garratt, Douglas

AU - Ghrist, Aaron M.

AU - Graßl, Martin

AU - Kling, Matthias F.

AU - Larsen, Kirk A.

AU - Liang, Mengning

AU - Lin, Ming Fu

AU - Liu, Yusong

AU - Minitti, Michael P.

AU - Nelson, Silke

AU - Robinson, Joseph S.

AU - Bucksbaum, Philip H.

AU - Wolf, Thomas J.A.

AU - List, Nanna H.

AU - Glownia, James M.

PY - 2025/8/20

Y1 - 2025/8/20

N2 - We have observed the signatures of valence electron rearrangement in photoexcited ammonia using ultrafast hard x-ray scattering. Time-resolved x-ray scattering is a powerful tool for imaging structural dynamics in molecules because of the strong scattering from the core electrons localized near each nucleus. Such core-electron contributions generally dominate the differential scattering signal, masking any signatures of rearrangement in the chemically important valence electrons. Ammonia represents an exception to the typically high core-to-valence electron ratio. We measured 9.8 keV x-ray scattering from gas-phase deuterated ammonia following photoexcitation via a 200 nm pump pulse to the 3s Rydberg state. We observed changes in the recorded scattering patterns due to the initial photoexcitation and subsequent deuterium dissociation. Ab initio calculations confirm that the observed signal is sensitive to the rearrangement of the single photoexcited valence electron as well as the interplay between adiabatic and nonadiabatic dissociation channels. The use of ultrafast hard x-ray scattering to image the structural rearrangement of single valence electrons constitutes an important advance in tracking valence electronic structure in photoexcited atoms and molecules.

AB - We have observed the signatures of valence electron rearrangement in photoexcited ammonia using ultrafast hard x-ray scattering. Time-resolved x-ray scattering is a powerful tool for imaging structural dynamics in molecules because of the strong scattering from the core electrons localized near each nucleus. Such core-electron contributions generally dominate the differential scattering signal, masking any signatures of rearrangement in the chemically important valence electrons. Ammonia represents an exception to the typically high core-to-valence electron ratio. We measured 9.8 keV x-ray scattering from gas-phase deuterated ammonia following photoexcitation via a 200 nm pump pulse to the 3s Rydberg state. We observed changes in the recorded scattering patterns due to the initial photoexcitation and subsequent deuterium dissociation. Ab initio calculations confirm that the observed signal is sensitive to the rearrangement of the single photoexcited valence electron as well as the interplay between adiabatic and nonadiabatic dissociation channels. The use of ultrafast hard x-ray scattering to image the structural rearrangement of single valence electrons constitutes an important advance in tracking valence electronic structure in photoexcited atoms and molecules.

U2 - 10.1103/53h3-vykl

DO - 10.1103/53h3-vykl

M3 - Article

C2 - 40929341

AN - SCOPUS:105015782346

SN - 0031-9007

VL - 135

SP - 83001

JO - Physical Review Letters

JF - Physical Review Letters

IS - 8

ER -

Imaging Valence Electron Rearrangement in a Chemical Reaction Using Hard X-Ray Scattering

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