Identification of optical magnetic resonances generated in a neon discharge by coherent transitions of spatially separated isotopically different atoms
Saprykin E. G. 1
1Institute of Automation and Electrometry, Siberian BranchRussian Academy of Sciences, Novosibirsk, Russia
Email: Saprykin@iae.nsk.su
Infrared (IR) transitions are identified in the neon spectrum in the range 0.76-15.8 μm, they generate resonances due to quadrature field synchronization of spatially separated isotopically different atoms. The use of numerical methods for the analysis of low-contrast IR resonances made it possible to estimate the previously unknown isotopic shifts of their parent transitions levels. A change in the amplitude sign of quadrature optical-magnetic resonances with a change in the isotopic shift sign of the transitions that generate them is found, and the dependence of the lifetime of such coherent atom pairs on the transitions wavelength is recorded, showing an unusual reaching the plateau as the wavelength decreases. It is assumed that this is due to expansion of the response time of the neighboring excited atoms of the isotopic pair to their fields interference. Keywords: neon, IR transitions, field interference, coherent atom pairs.
- E.G. Saprykin, V.A. Sorokin. In: IVth Int. Symposium Modern Problems of Laser Physics (Novosibirsk, 2004), p. 240
- E.G. Saprykin, V.A. Sorokin. In collected volume: Proceedings of the IV International Conference ?Problems of Fundamental Optics? (St.-Petersburg, 2006), p. 173
- M.P. Chayka. Interferentsiya vyrozhdennykh sostoyaniy (L.: Izd-vo LGU, 1975) (in Russian)
- E.B. Alexandrov, G.I. Kvostenko, M.P. Chayka. Interferentsiya atomnykh sostoyaniy (M.: Nauka, 1991) (in Russian). E.G. Saprykin, V.A. Sorokin. Opt. i spektr., 109, 573 (2010) (in Russian)
- E.G. Saprykin, V.A. Sorokin, A.M. Shalagin. ZhETF, 143, 622 (2013) (in Russian)
- V.A. Sorokin. In: Sixth Int. Simposium Modern Problem of Laser Physics (Novosibirsk, 2013), p. 241-242
- E.G. Saprykin, V.A. Sorokin. Opt. i spektr., 117, 18 (2014) (in Russian)
- E.G. Saprykin, V.A. Sorokin, A.M. Shalagin. Quant. electron., 48, 827 (2015) (in Russian)
- E.G. Saprykin. ZhETF, 149, 251 (2016) (in Russian)
- E.G. Saprykin. Opt. i spektr., 122, 568 (2017) (in Russian)
- R. Feynman, R. Leighton., M. Sands. Feynman Lectures on Physics. Vol. 5. Electricity and magnetism. (M.: Mir, 1977)
- L.V. Ilyichev. ZhETF, 131, 30 (2007) (in Russian)
- R.H. Dicke. Phys. Rev., 93, 99 (1954)
- A.A. Makarov, V.S. Letokhov. ZhETF, 124, 766 (2003) (in Russian)
- W. B. Westerveld, J. van Eck. J. Phys. B., 12, 377 (1979)
- K.S.E. Eikema, W. Ubachs, W. Hogervorst. Phys. Rev. A., 49, 803 (1994)
- H. Shober. Pys. Zs., 40, 77 (1939)
- E.G. Saprykin. Opt. i spektr., 120, 222 (2016) (in Russian)
- E.G. Saprykin. Opt. i spektr., 127, 179 (2019) (in Russian)
- E.G. Saprykin. Opt. i spektr., 123, 285 (2017) (in Russian)
- J.C. Keller, J.F. Lesprit. Physica., 64, 202 (1973)
- P.F. Gruzdev. Veroyatnosti perekhodov i radiatsionnyye vremena zhizni urovney atomov i ionov (M.: Energoatomizdat, 1990) (in Russian)
- J.D. Macomber. The Dynamics of Spectroscopic Transitions (New York-London-Sydney-Toronto: John Wiley and Sons, 1976). [J.D. McComber. Dynamics of spectroscopic transitions (M.: Mir, 1979).]
Подсчитывается количество просмотров абстрактов ("html" на диаграммах) и полных версий статей ("pdf"). Просмотры с одинаковых IP-адресов засчитываются, если происходят с интервалом не менее 2-х часов.
Дата начала обработки статистических данных - 27 января 2016 г.