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Observation of site-selective chemical bond changes via ultrafast chemical shifts

André Al Haddad, Soléne Oberli, Jesús González‐Vázquez, Maximilian Bucher, Gilles Doumy, Phay J. Ho, J. Krzywiński, Thomas J. Lane, Alberto Lutman, Agostino Marinelli, T. Maxwell, Stefan Moeller, S. T. Pratt, D. Ray, Ron Shepard, S. H. Southworth, Álvaro Vázquez‐Mayagoitia, Peter Walter, Linda Young, Antonio Picón, Christoph Bostedt

2022Nature Communications18 citationsDOIOpen Access PDF

Abstract

The concomitant motion of electrons and nuclei on the femtosecond time scale marks the fate of chemical and biological processes. Here we demonstrate the ability to initiate and track the ultrafast electron rearrangement and chemical bond breaking site-specifically in real time for the carbon monoxide diatomic molecule. We employ a local resonant x-ray pump at the oxygen atom and probe the chemical shifts of the carbon core-electron binding energy. We observe charge redistribution accompanying core-excitation followed by Auger decay, eventually leading to dissociation and hole trapping at one site of the molecule. The presented technique is general in nature with sensitivity to chemical environment changes including transient electronic excited state dynamics. This work provides a route to investigate energy and charge transport processes in more complex systems by tracking selective chemical bond changes on their natural timescale.

Topics & Concepts

Chemical physicsChemical bondExcited stateAtomic physicsMoleculeAugerChemical reactionFemtosecondDissociation (chemistry)ExcitationChemistryElectronMolecular physicsPhotochemistryMaterials sciencePhysicsPhysical chemistryOrganic chemistryBiochemistryQuantum mechanicsLaserOpticsLaser-Matter Interactions and ApplicationsAdvanced Chemical Physics StudiesSpectroscopy and Quantum Chemical Studies
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