Imaging and controlling proton motion in molecules

How do atoms move within a molecule? What are the paths they take? Coulomb Explosion Imaging combined with a multi-color pump probe scheme allows us to address these questions with a table top setup. Since the momentum information of molecular fragments is preserved at the moment of explosion, we ca...

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Bibliographic Details
Main Authors: Ibrahim, H., Beaulieu, S., Wanie, V., Endo, T., Wales, B., Tong, X.-M., Schuurman, M. S., Sanderson, J., Légaré, F.
Format: Conference Proceeding
Language:English
Subjects:
Acetylene
Cations
Color
Deuterons
Explosions
Fragmentation
Fragments
Infrared lasers
Ionization
Isomerization
Localization
Migration
Molecular structure
Position (location)
Protons
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Summary:How do atoms move within a molecule? What are the paths they take? Coulomb Explosion Imaging combined with a multi-color pump probe scheme allows us to address these questions with a table top setup. Since the momentum information of molecular fragments is preserved at the moment of explosion, we can deduce the fragment’s momentary position, representing the structure of the molecule. We have studied isomerization and dissociation events through the movement of protons, deuterons and electrons, taking advantage of the rich statistics this technique provides. In the case of proton migration in the acetylene cation, we were able to identify an isotope dependent to- and fro isomerization behavior [1]. Presently, we are expanding our studies on more complex processes. Aside from passively studying dynamics, we have also actively controlled the electron localization in small molecules [2] using two-color mid-infrared asymmetric laser fields. The manipulation of protons, the lightest atomic fragments in molecules, is of great interest due to the tremendous diversity of molecules containing them, in combination with the generality of how protons behave within molecules. Their detection involves certain challenges since they move extremely fast compared to heavier atoms. Here, we focus on two different proton motions which are triggered by excitation with ultrashort laser pulses and imaged with the Coulomb explosion imaging (CEI) technique. First, we will discuss proton migration dynamics in the acetylene cation launched due to strong field multiphoton ionization with UV pulses in a rather simple table top approach. Second, we will concentrate on controlling electron localization – and thus proton localization – in the cation of the hydrogen molecule by using an asymmetric two color field in the mid-infrared (MIR).
ISSN:0094-243X
1551-7616
DOI:10.1063/1.5012304