Laser isotope separation has emerged as a promising technique for the selective separation of 13C isotope, offering a simple setup, high selectivity, and low energy consumption. Contrary to a previous… Click to show full abstract
Laser isotope separation has emerged as a promising technique for the selective separation of 13C isotope, offering a simple setup, high selectivity, and low energy consumption. Contrary to a previous study, we found that increasing the pulse repetition rate to enhance production rate actually leads to a decrease in 13C selectivity. This decline is attributed to energy accumulation within the irradiated region, inducing thermal excitation, increased molecular collision frequency and non-selective dissociation related to V-V, V-R and V-T energy transfers. To eliminate these negative effects, we recommend using an absorption cell with a gas exchange system to guarantee that each laser pulse interacts with fresh gas molecules. The selectivity decline can also be mitigated by using a vibrational relaxer, such as argon. Another alternative to maintain selectivity is increasing the wavelength. The underlying mechanisms are further elaborated through a perspective of molecular dynamics.
               
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