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Metallic water: Transient state under ultrafast electronic excitation

Nikita Medvedev, R. Voronkov, А. Е. Волков

2023The Journal of Chemical Physics10 citationsDOIOpen Access PDF

Abstract

The modern means of controlled irradiation by femtosecond lasers or swift heavy ion beams can transiently produce such energy densities in samples that reach collective electronic excitation levels of the warm dense matter state, where the potential energy of interaction of the particles is comparable to their kinetic energies (temperatures of a few eV). Such massive electronic excitation severely alters the interatomic potentials, producing unusual nonequilibrium states of matter and different chemistry. We employ density functional theory and tight binding molecular dynamics formalisms to study the response of bulk water to ultrafast excitation of its electrons. After a certain threshold electronic temperature, the water becomes electronically conducting via the collapse of its bandgap. At high doses, it is accompanied by nonthermal acceleration of ions to a temperature of a few thousand Kelvins within sub-100 fs timescales. We identify the interplay of this nonthermal mechanism with the electron-ion coupling, enhancing the electron-to-ions energy transfer. Various chemically active fragments are formed from the disintegrating water molecules, depending on the deposited dose.

Topics & Concepts

ExcitationAtomic physicsThermalisationIonElectronFemtosecondElectron excitationChemical physicsMaterials scienceSolvated electronMolecular physicsChemistryIrradiationLaserPhysicsRadiolysisOpticsNuclear physicsQuantum mechanicsOrganic chemistrySpectroscopy and Quantum Chemical StudiesIon-surface interactions and analysisLaser-Matter Interactions and Applications
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