Infrared laser-induced isotope-selective dissociation of mixed (CF3Br)mArnvan der Waals clusters

Петин, А. Н.; Макаров, Г. Н.

doi:10.1070/qel16912

Quantum Electron.

2019

DOI: 10.1070/qel16912

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Infrared laser-induced isotope-selective dissociation of mixed (CF₃Br)_mAr_nvan der Waals clusters

А. Н. Петин¹,

Г. Н. Макаров²

Abstract: The paper presents the results of studies of IR laser-induced bromine-isotope-selective dissociation of small mixed (CF3Br) m Ar n van der Waals clusters (m = 1, 2 and 1 ≤ n ≤ 5 is the number of molecules and atoms in the clusters, respectively). The experiments used a pulsed CO2 laser to excite clusters and a quadrupole mass spectrometer to detect a molecular cluster beam. The research method is based on the selective vibrational e… Show more

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Cited by 14 publications

References 42 publications

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Strong mutual increase in the efficiency of isotope-selective laser IR dissociation of molecules under nonequilibrium thermodynamic conditions of the compression shock under irradiation in a bimolecular mixture

Макаров¹,

Петин²

2020

Quantum Electron.

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We have revealed a strong (by a factor of 2 to 5) mutual increase in the yield of IR molecular dissociation (by the example of CF2HCl and CF3Br) and a significant (by a factor of 1.5 to 3) lowering of dissociation thresholds in the nonequilibrium thermodynamic conditions of compression shock in the irradiation of the molecules by resonance IR laser radiation in the bimolecular mixture in comparison with their individual irradiation. This opens up the possibility to perform efficient isotope-selective IR dissociation of molecules at lower excitation energy densities (Φ ⩽ 1.5 – 2.0 J cm−2) and thereby to improve the dissociation selectivity. This was demonstrated by the example of chlorine- and bromine-isotope selective dissociation of the specified molecules, which are characterised by quite small (less than 0.25 cm−1) isotope shifts in the IR vibrational absorption spectra excited by laser radiation. The enrichment coefficients K enr(35Cl / 37Cl) = 0.90 ± 0.05 in the residual CF2HCl gas and K enr(79Br / 81Br) in the resultant Br2 product are obtained when the CF2HCl : CF3Br = 1 : 1 molecular mixture and CF3Br molecules, respectively, are irradiated by the 9R(30) CO2 laser line (frequency, 1084.635 cm−1) at an energy density Φ ≈ 1.3 J cm−2.

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Strong mutual increase in the efficiency of isotope-selective laser IR dissociation of molecules under nonequilibrium thermodynamic conditions of the compression shock under irradiation in a bimolecular mixture

Макаров¹,

Петин²

2020

Quantum Electron.

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Possibility of resonant three-photon isotope-selective excitation of vibrational states with υ = 3 of the UF₆molecule mode ν₃by radiation from two pulsed IR lasers in a gas-dynamically cooled molecular flow

Макаров¹

2021

Quantum Electron.

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We consider the possibility of resonant isotope-selective population of states with υ = 3 of the vibrational mode ν 3 of UF6 molecules as a result of three-photon bichromatic excitation of the molecules by IR radiation from two pulsed CF4 lasers and two pulsed para-H2 lasers. We propose specific schemes and analyse the possibility of exciting the 238UF6 and 235UF6 molecules into states with υ = 3 of the vibrational mode ν 3 using two CF4 lasers (or para-H2 lasers) generating in the region of 16 μm at frequencies that are significantly (by ∼3.5 – 17 cm−1) detuned from the linear absorption bands at the frequencies of ν 3 vibration of these molecules in a gas-dynamically cooled molecular flow. However, the sum of the doubled lasing frequency 2ν L1 of the first laser and the frequency ν L2 of the second laser is equal to a frequency of the transition υ = 0 → υ = 3 of the vibrational mode ν 3 of the UF6 molecules. When both laser pulses coincide in time, the possibility of selective excitation of UF6 molecules from the ground vibrational state with υ = 0 to the state with υ = 3 of the vibrational mode ν 3 is realised. The proposed schemes for the excitation of UF6 molecules to states with υ = 3 are compared with the previously implemented schemes for the effective excitation of states with υ = 3 of the vibrational mode ν 3 (F 1) and states with υ = 2 of the vibrational mode ν 3 (A 1) of SF6 molecules by three- and two-frequency radiation of pulsed CO2 lasers, respectively.

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Isotope-Selective Infrared Laser Dissociation of Molecules with a Small Isotopic Shift in a Gas-Dynamically Cooled Molecular Flow Interacting with a Solid Surface

Макаров

Петин

2020

Jetp Lett.

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Infrared laser-induced isotope-selective dissociation of mixed (CF₃Br)_mAr_nvan der Waals clusters

Cited by 14 publications

References 42 publications

Strong mutual increase in the efficiency of isotope-selective laser IR dissociation of molecules under nonequilibrium thermodynamic conditions of the compression shock under irradiation in a bimolecular mixture

Strong mutual increase in the efficiency of isotope-selective laser IR dissociation of molecules under nonequilibrium thermodynamic conditions of the compression shock under irradiation in a bimolecular mixture

Possibility of resonant three-photon isotope-selective excitation of vibrational states with υ = 3 of the UF₆molecule mode ν₃by radiation from two pulsed IR lasers in a gas-dynamically cooled molecular flow

Isotope-Selective Infrared Laser Dissociation of Molecules with a Small Isotopic Shift in a Gas-Dynamically Cooled Molecular Flow Interacting with a Solid Surface

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Infrared laser-induced isotope-selective dissociation of mixed (CF3Br)mArnvan der Waals clusters

Cited by 14 publications

References 42 publications

Strong mutual increase in the efficiency of isotope-selective laser IR dissociation of molecules under nonequilibrium thermodynamic conditions of the compression shock under irradiation in a bimolecular mixture

Strong mutual increase in the efficiency of isotope-selective laser IR dissociation of molecules under nonequilibrium thermodynamic conditions of the compression shock under irradiation in a bimolecular mixture

Possibility of resonant three-photon isotope-selective excitation of vibrational states with υ = 3 of the UF6molecule mode ν3by radiation from two pulsed IR lasers in a gas-dynamically cooled molecular flow

Isotope-Selective Infrared Laser Dissociation of Molecules with a Small Isotopic Shift in a Gas-Dynamically Cooled Molecular Flow Interacting with a Solid Surface

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Product

Resources

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Infrared laser-induced isotope-selective dissociation of mixed (CF₃Br)_mAr_nvan der Waals clusters

Possibility of resonant three-photon isotope-selective excitation of vibrational states with υ = 3 of the UF₆molecule mode ν₃by radiation from two pulsed IR lasers in a gas-dynamically cooled molecular flow