Formation of CN Radical from Nitrogen and Carbon Condensation and from Photodissociation in Femtosecond Laser-Induced Plasmas: Time-Resolved FT-UV–Vis Spectroscopic Study of the Violet Emission of CN Radical

Exploring the formation of diatomic radicals in femtosecond plasmas is important to establish the most dominant kinetic pathways following ionization and dissociation of small molecules. In this work, cyano radical formation has been studied from bromoform, acetonitrile, and methanol in nitrogen and...

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Published in:The journal of physical chemistry. A, Molecules, spectroscopy, kinetics, environment, & general theory Molecules, spectroscopy, kinetics, environment, & general theory, 2020-04, Vol.124 (14), p.2755-2767
Main Authors: Mogyorosi, K, Sarosi, K, Seres, I, Jojart, P, Fule, M, Chikan, V
Format: Article
Language:English
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Summary:Exploring the formation of diatomic radicals in femtosecond plasmas is important to establish the most dominant kinetic pathways following ionization and dissociation of small molecules. In this work, cyano radical formation has been studied from bromoform, acetonitrile, and methanol in nitrogen and argon plasmas created with a focused femtosecond laser beam operating at 100 kHz repetition rate and 1030 nm wavelength with 43 fs pulse length and 250 μJ pulse energy. Time-resolved Fourier transform fluorescence spectroscopy was applied in the ultraviolet–visible (UV–vis) spectral range for the characterization of the rotational and vibrational temperatures of the CN­(B) radicals via fitting the experimental data. The high repetition rate of the laser allows efficient coupling with the step-scan Fourier transform spectroscopy method. Coulomb explosion at the very high intensity (∼1016 W/cm2) resulted in the formation of nascent atoms, ions, and electrons. The condensation reactions of carbon and reactive nitrogen species resulted in the formation of CN­(B2Σ+) radicals and C2(d3Πg) dicarbon molecules/radicals. The CN­(B) radicals were formed at the highest concentration in the case of bromoform because the weak carbon–bromine bonds resulted in reactive carbon atoms and CH radicals, which are reactive precursors for the CN­(B) radical formation. In the case of acetonitrile, immediate production of CN­(B) is observed with nanosecond resolution, which suggests that the CN is formed either via photodetachment or via roaming reaction associated with the Coulomb explosion of the parent molecule. The nascent rotational temperature was very high (∼6000–8500 K) and rapidly decreased in all instances within 40 ns with bromoform and acetonitrile. The highest vibrational temperature (∼7800 K) was observed in an acetonitrile/Ar mixture that decreased in about 30 ns and then increased in the observed time window. The vibrational temperature increased in all samples between 30 and 200 ns. The time dependence of fluorescence is described with a monoexponential decay in the case of acetonitrile/Ar and with biexponential decays in all other instances in the 0–250 mbar total pressure range. The shorter time constant is close to the radiative lifetime of CN­(B) emission (∼60–80 ns), which can be attributed to the CN­(B) radicals produced in the first few collisions at lower pressures. The longer CN­(B) emission is from CN­(B) created by slower chemical reactions involving carbon
ISSN:1089-5639
1520-5215
DOI:10.1021/acs.jpca.0c00361