1 research outputs found
Time-Resolved Kinetic Chirped-Pulse Rotational Spectroscopy in a Room-Temperature Flow Reactor
Chirped-pulse Fourier
transform millimeter-wave spectroscopy is
a potentially powerful tool for studying chemical reaction dynamics
and kinetics. Branching ratios of multiple reaction products and intermediates
can be measured with unprecedented chemical specificity; molecular
isomers, conformers, and vibrational states have distinct rotational
spectra. Here we demonstrate chirped-pulse spectroscopy of vinyl cyanide
photoproducts in a flow tube reactor at ambient temperature of 295
K and pressures of 1–10 μbar. This <i>in situ</i> and time-resolved experiment illustrates the utility of this novel
approach to investigating chemical reaction dynamics and kinetics.
Following 193 nm photodissociation of CH<sub>2</sub>CHCN, we observe
rotational relaxation of energized HCN, HNC, and HCCCN photoproducts
with 10 μs time resolution and sample the vibrational population
distribution of HCCCN. The experimental branching ratio HCN/HCCCN
is compared with a model based on RRKM theory using high-level ab
initio calculations, which were in turn validated by comparisons to
Active Thermochemical Tables enthalpies