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Simulating pump-probe photo-electron and absorption spectroscopy on the attosecond time-scale with time-dependent density-functional theory

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arxiv 1301.1958 v1 pith:3325WTEC submitted 2013-01-09 physics.atm-clus physics.atom-phphysics.chem-phphysics.plasm-ph

Simulating pump-probe photo-electron and absorption spectroscopy on the attosecond time-scale with time-dependent density-functional theory

classification physics.atm-clus physics.atom-phphysics.chem-phphysics.plasm-ph
keywords absorptiontime-dependentattoseconddensity-functionalelectronicexperimentsextendedphoto-electron
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Molecular absorption and photo-electron spectra can be efficiently predicted with real-time time-dependent density-functional theory (TDDFT). We show here how these techniques can be easily extended to study time-resolved pump-probe experiments in which a system response (absorption or electron emission) to a probe pulse, is measured in an excited state. This simulation tool helps to interpret the fast evolving attosecond time-resolved spectroscopic experiments, where the electronic motion must be followed at its natural time-scale. We show how the extra degrees of freedom (pump pulse duration, intensity, frequency, and time-delay), which are absent in a conventional steady state experiment, provide additional information about electronic structure and dynamics that improve a system characterization. As an extension of this approach, time-dependent 2D spectroscopies can also be simulated, in principle, for large-scale structures and extended systems.

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