Abstract
The correlation between chemical structure and predissociation dynamics has been evaluated for a series of linear and branched alkyl iodides with increasing structural complexity by means of femtosecond time-resolved velocity map imaging experiments following excitation on the second absorption band (B-band) at around 201 nm. The time-resolved images for the iodine fragment are reported and analyzed in order to extract electronic predissociation lifetimes and the temporal evolution of the anisotropy while the experimental results are supported by ab initio calculations of the potential energy curves as a function of the C-I distance. Remarkable similarities are observed for all molecules consistent with a major predissociation of the initially populated bound Rydberg states 6A″ and 7A′ through a crossing with the purely repulsive states 7A″, 8A′ and 8A″ leading to a major R + I*(2P1/2) (R = CH3, C2H5, n-C3H7, n-C4H9, i-C3H7 and t-C4H9) dissociation channel. The reported electronic predissociation lifetimes are found to decrease for an increasing size of the linear radical, reflecting the shifts observed in the position of the crossings in the potential energy curves, and very likely a greater non-adiabatic coupling between the initially populated Rydberg states and the repulsive states leading to dissociation induced by other coordinates associated to key vibrational normal modes. The loss of anisotropy is fully accounted for by the parent molecular rotation during predissociation and the rotational temperature of the parent molecule in the molecular beam is reasonably derived.
Highlights
The correlation between chemical structure and predissociation dynamics has been evaluated for a series of linear and branched alkyl iodides with increasing structural complexity by means of femtosecond time-resolved velocity map imaging experiments following excitation on the second absorption band (B-band) at around 201 nm
We study the time-resolved predissociation of a series of linear (CH3I, C2H5I, n-C3H7I, n-C4H9I) and branched (i-C3H7I, t-C4H9I) alkyl iodides in the second absorption band, labeled B-band, following excitation around 201 nm
The resonance enhanced multiphoton ionization (REMPI) scheme allows the simultaneous detection of both I and I* fragment spin-orbit states, a single perpendicular ring, attributed to the R + I* dissociation channel, is observed in all images becoming broader as the size of the molecule increases
Summary
The correlation between chemical structure and predissociation dynamics has been evaluated for a series of linear and branched alkyl iodides with increasing structural complexity by means of femtosecond time-resolved velocity map imaging experiments following excitation on the second absorption band (B-band) at around 201 nm. The correlation between increasing structural complexity of alkyl iodides and the ultrafast C-I bond cleavage was investigated by our group employing femtosecond time-resolved velocity map imaging (VMI)[2] in conjunction with ab initio full-dimension time-resolved dynamics calculations For this purpose, a series of linear and branched alkyl iodide molecules were excited at 266 nm in the first absorption band (A-band) which arises from the n(5p,I) → σ*(C—I) transition[3]. The goal here is to investigate the effect of key structural changes on the photodynamics of a prototypical electronic predissociation reaction For this purpose, we study the time-resolved predissociation of a series of linear (CH3I, C2H5I, n-C3H7I, n-C4H9I) and branched (i-C3H7I, t-C4H9I) alkyl iodides in the second absorption band, labeled B-band, following excitation around 201 nm.
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