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This article is cited in 16 scientific papers (total in 16 papers)
Laser isotope separation
Selective IR multiphoton dissociation of molecules in a pulsed gas-dynamically cooled molecular flow interacting with a solid surface as an alternative to low-energy methods of molecular laser isotope separation
G. N. Makarova, A. N. Petinab a Institute of Spectroscopy, Russian Academy of Sciences, Troitsk, Moscow
b Troitsk Institute for Innovation and Fusion Research
Abstract:
We report the results of studies on the isotope-selective infrared multiphoton dissociation (IR MFD) of SF6 and CF3I molecules in a pulsed, gas-dynamically cooled molecular flow interacting with a solid surface. The productivity of this method in the conditions of a specific experiment (by the example of SF6 molecules) is evaluated. A number of low-energy methods of molecular laser isotope separation based on the use of infrared lasers for selective excitation of molecules are analysed and their productivity is estimated. The methods are compared with those of selective dissociation of molecules in the flow interacting with a surface. The advantages of this method compared to the low-energy methods of molecular laser isotope separation and the IR MPD method in the unperturbed jets and flows are shown. It is concluded that this method could be a promising alternative to the low-energy methods of molecular laser isotope separation.
Keywords:
atoms, molecules, clusters, molecular and cluster beams, laser spectroscopy, laser-induced selective processes, laser isotope separation.
Received: 18.06.2015 Revised: 01.12.2015
Citation:
G. N. Makarov, A. N. Petin, “Selective IR multiphoton dissociation of molecules in a pulsed gas-dynamically cooled molecular flow interacting with a solid surface as an alternative to low-energy methods of molecular laser isotope separation”, Kvantovaya Elektronika, 46:3 (2016), 248–254 [Quantum Electron., 46:3 (2016), 248–254]
Linking options:
https://www.mathnet.ru/eng/qe16342 https://www.mathnet.ru/eng/qe/v46/i3/p248
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Abstract page: | 209 | Full-text PDF : | 64 | References: | 24 | First page: | 8 |
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