Jan Troß scite author profile

Photo-induced isomerization reactions lie at the heart of many chemical processes in nature. The mechanisms of such reactions are determined by a delicate interplay of coupled electronic and nuclear dynamics occurring on the femtosecond scale, followed by the slower redistribution of energy into different vibrational degrees of freedom. Here we apply time-resolved photoelectron spectroscopy with a seeded extreme ultraviolet free-electron laser to trace the ultrafast ring opening of gas-phase thiophenone molecules following ultraviolet photoexcitation. When combined with ab initio electronic-structure and molecular-dynamics calculations of the excitedand ground-state molecules, the results provide insights into both the electronic and nuclear dynamics of this fundamental class of reactions. The initial ring opening and non-adiabatic coupling to the electronic ground state is shown to be driven by ballistic S-C bond extension and to be complete within 350 femtoseconds. Theory and experiment also enable visualization of the rich ground-state dynamics -involving formation of, and interconversion between, ring-opened isomers and the cyclic structure, and fragmentation over much longer timescales.

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Measuring the angle-dependent photoionization cross section of nitrogen using high-harmonic generation

Ren

Makhija

et al. 2013

Phys. Rev. A

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We exploit the relationship between high harmonic generation (HHG) and the molecular photorecombination dipole to extract the molecular-frame differential photoionization cross section (PICS) in the extreme ultraviolet (XUV) for molecular nitrogen. A shape resonance and a Cooper-type minimum are reflected in the pumpprobe time delay measurements of different harmonic orders, where high-order rotational revivals are observed in N 2 . We observe the energy-and angle-dependent Cooper minimum and shape resonance directly in the laboratory-frame HHG yield by achieving a high degree of alignment, cos 2 θ 0.8. The interplay between PICS and rotational revivals is confirmed by simulations using the quantitative rescattering theory. Our method of extracting molecular-frame structural information points the way to similar measurements in more complex molecules.

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Imaging the Temporal Evolution of Molecular Orbitals during Ultrafast Dissociation

et al. 2016

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Differentiating and Quantifying Gas-Phase Conformational Isomers Using Coulomb Explosion Imaging

Pathak

Obaid

Bhattacharyya

et al. 2020

J. Phys. Chem. Lett.

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Conformational isomerism plays a crucial role in defining the physical and chemical properties and biological activity of molecules ranging from simple organic compounds to complex biopolymers. However, it is often a significant challenge to differentiate and separate these isomers experimentally as they can easily interconvert due to their low rotational energy barrier. Here, we use the momentum correlation of fragment ions produced after inner-shell photoionization to distinguish conformational isomers of 1,2-dibromoethane (C2H4Br2). We demonstrate that the three-body breakup channel, C2H4 + + Br+ + Br+, contains signatures of both sequential and concerted breakup, which are decoupled to distinguish the geometries of two conformational isomers and to quantify their relative abundance. The sensitivity of our method to quantify these yields is established by measuring the relative abundance change with sample temperature, which agrees well with calculations. Our study paves the way for using Coulomb explosion imaging to track subtle molecular structural changes.

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Jan Troß

Tracking the ultraviolet-induced photochemistry of thiophenone during and after ultrafast ring opening

Measuring the angle-dependent photoionization cross section of nitrogen using high-harmonic generation

Imaging the Temporal Evolution of Molecular Orbitals during Ultrafast Dissociation

Differentiating and Quantifying Gas-Phase Conformational Isomers Using Coulomb Explosion Imaging

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