Direct observation of ring-opening dynamics in strong-field ionized selenophene using femtosecond inner-shell absorption spectroscopy

Direct observation of ring-opening dynamics in strong-field ionized selenophene using femtosecond inner-shell absorption spectroscopy

Femtosecond extreme ultraviolet transient absorption spectroscopy is used to explore strong-field ionization induced dynamics in selenophene (C4H4Se). The dynamics are monitored in real-time from the viewpoint of the Se atom by recording the temporal evolution of element-specific spectral features n...

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Veröffentlicht in:The Journal of chemical physics 2016-12, Vol.145 (23), p.234313-234313
Hauptverfasser: Lackner, Florian, Chatterley, Adam S., Pemmaraju, C. D., Closser, Kristina D., Prendergast, David, Neumark, Daniel M., Leone, Stephen R., Gessner, Oliver
Format: Artikel
Sprache:eng
Schlagworte:
Absorption spectroscopy
Cations
Density functional theory
Dynamics
Emergence
Field ionization
First principles
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Molecular ions
Organic chemistry
Photochemical reactions
Real time
Recording
Spectrum analysis
Time dependence
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container_end_page 234313
container_issue 23
container_start_page 234313
container_title The Journal of chemical physics
container_volume 145
creator Lackner, Florian
Chatterley, Adam S.
Pemmaraju, C. D.
Closser, Kristina D.
Prendergast, David
Neumark, Daniel M.
Leone, Stephen R.
Gessner, Oliver
description Femtosecond extreme ultraviolet transient absorption spectroscopy is used to explore strong-field ionization induced dynamics in selenophene (C4H4Se). The dynamics are monitored in real-time from the viewpoint of the Se atom by recording the temporal evolution of element-specific spectral features near the Se 3d inner-shell absorption edge (∼58 eV). The interpretation of the experimental results is supported by first-principles time-dependent density functional theory calculations. The experiments simultaneously capture the instantaneous population of stable molecular ions, the emergence and decay of excited cation states, and the appearance of atomic fragments. The experiments reveal, in particular, insight into the strong-field induced ring-opening dynamics in the selenophene cation, which are traced by the emergence of non-cyclic molecules as well as the liberation of Se+ ions within an overall time scale of approximately 170 fs. We propose that both products may be associated with dynamics on the same electronic surfaces but with different degrees of vibrational excitation. The time-dependent inner-shell absorption features provide direct evidence for a complex relaxation mechanism that may be approximated by a two-step model, whereby the initially prepared, excited cyclic cation decays within τ 1 = 80 ± 30 fs into a transient molecular species, which then gives rise to the emergence of bare Se+ and ring-open cations within an additional τ 2 = 80 ± 30 fs. The combined experimental and theoretical results suggest a close relationship between σ* excited cation states and the observed ring-opening reactions. The findings demonstrate that the combination of femtosecond time-resolved core-level spectroscopy with ab initio estimates of spectroscopic signatures provide new insights into complex, ultrafast photochemical reactions such as ring-opening dynamics in organic molecules in real-time and with simultaneous sensitivity for electronic and structural rearrangements.
doi_str_mv 10.1063/1.4972258
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The dynamics are monitored in real-time from the viewpoint of the Se atom by recording the temporal evolution of element-specific spectral features near the Se 3d inner-shell absorption edge (∼58 eV). The interpretation of the experimental results is supported by first-principles time-dependent density functional theory calculations. The experiments simultaneously capture the instantaneous population of stable molecular ions, the emergence and decay of excited cation states, and the appearance of atomic fragments. The experiments reveal, in particular, insight into the strong-field induced ring-opening dynamics in the selenophene cation, which are traced by the emergence of non-cyclic molecules as well as the liberation of Se+ ions within an overall time scale of approximately 170 fs. We propose that both products may be associated with dynamics on the same electronic surfaces but with different degrees of vibrational excitation. The time-dependent inner-shell absorption features provide direct evidence for a complex relaxation mechanism that may be approximated by a two-step model, whereby the initially prepared, excited cyclic cation decays within τ 1 = 80 ± 30 fs into a transient molecular species, which then gives rise to the emergence of bare Se+ and ring-open cations within an additional τ 2 = 80 ± 30 fs. The combined experimental and theoretical results suggest a close relationship between σ* excited cation states and the observed ring-opening reactions. 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subjects Absorption spectroscopy
Cations
Density functional theory
Dynamics
Emergence
Field ionization
First principles
INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY
Molecular ions
Organic chemistry
Photochemical reactions
Real time
Recording
Spectrum analysis
Time dependence
title Direct observation of ring-opening dynamics in strong-field ionized selenophene using femtosecond inner-shell absorption spectroscopy
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