Abstract
Velocity map imaging methods, with a new and improved ion optics design, have been used to explore the near ultraviolet photodissociation dynamics of gas phase 2-bromo- and 2-iodothiophene molecules. In both cases, the ground (X) and spin-orbit excited (X*) (where X = Br, I) atom products formed at the longest excitation wavelengths are found to recoil with fast, anisotropic velocity distributions, consistent with prompt C-X bond fission following excitation via a transition whose dipole moment is aligned parallel to the breaking bond. Upon tuning to shorter wavelengths, this fast component fades and is progressively replaced by a slower, isotropic recoil distribution. Complementary electronic structure calculations provide a plausible explanation for this switch in fragmentation behaviour—namely, the opening of a rival C-S bond extension pathway to a region of conical intersection with the ground state potential energy surface. The resulting ground state molecules are formed with more than sufficient internal energy to sample the configuration space associated with several parent isomers and to dissociate to yield X atom products in tandem with both cyclic and ring-opened partner fragments.
Highlights
Near ultraviolet (UV) photoexcitation of an isolated gas phase molecule at energies above its lowest dissociation limit often results in bond fission
There is growing recognition that the excited state potential energy surface (PES) on which the eventual bond extension occurs is likely to arise as a result of electron promotion to a σ∗ orbital
The near UV photofragmentation dynamics of jet-cooled, gas phase 2-bromo- and 2-iodothiophene molecules have been investigated at many different excitation wavelengths by measuring the velocity distributions of the X/X∗ products using a VMI spectrometer equipped with a new, purpose designed ion optics assembly
Summary
Near ultraviolet (UV) photoexcitation of an isolated gas phase molecule at energies above its lowest dissociation limit often results in bond fission.
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