thesis
Time-resolved studies of the photodissociation of adenine
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Abstract
A novel time-resolved velocity map ion imaging (TR-VMI) experiment has been
constructed and successfully applied to the study of non-statistical dissociation
processes.
The photodissociation of NH3 following the population of the ν2
’ = 4 umbrella
vibrational mode of the first electronically excited, Ã1A2”, singlet state, was
initially studied. It was clearly observed that the N-H dissociation timescale was
inversely proportional to kinetic energy released to the H fragment. Assignment
of different kinetic energy regions of the TR-VMI transients to corresponding
bending vibrational modes (ν2) of the X2B1 state NH2 photoproduct clearly
suggests that dissociation into the vibrationless NH2 occurs in < 50 fs. Low
kinetic energy channels, show extended dissociation timescales, strongly
indicative of adiabatic dissociation to the first electronically excited state of NH2
(Ã2A1).
With an aim of modelling the photodissociation dynamics of adenine, the
photodissociation of pyrrole, imidazole, 2-methylimidazole, 4-methylimidazole
and 2,4-dimethylimidazole following excitation at 200 nm were studied using
time-resolved mass spectrometry (TR-MS) and VMI. In all cases ultrafast H
elimination was observed in < 130 fs, consistent with direct dissociation via the
repulsive 1πσ* potential energy surfaces. The photodissociation of 1-
methyimidazole at this wavelength was also studied. Once again ultrafast H
elimination was observed, but with greatly reduced yields, strongly suggesting H elimination from the non-heteroatom co-ordinates (C-H) also partaking in the
photodissociation dynamics at this wavelength.
TR-MS and VMI have also been applied to the study of the photodissociation of
adenine, 9-methyladenine and 6-dimethylaminopurine. In all measured kinetic
energy spectra a high kinetic energy channel has been observed, strongly
suggesting the participation of 1πσ* potential energy surfaces of both the azole
and amino co-ordinates in H elimination following excitation at 200 nm. Power
dependence studies at 266 nm suggest H elimination, but subsequent TR-MS
measurements seem to suggest that this is not due to the participation of the
1πσ* potential energy surfaces at this excitation wavelength