Research Article Open Access

Circular Rydberg States of Lithium Atoms or Lithium-Like Ions in a High-Frequency Laser Field: The Break of the Algebraic Symmetry

Nikolay Kryukov1 and Eugene Oks2
  • 1 Department of Physics, Universidad Nacional Autónoma de México, Mexico
  • 2 Department of Physics, Auburn University, United States

Abstract

There have been publications presenting studies of relatively simple atomic systems in a high-frequency laser field. The systems studied under such a field were highly excited (Rydberg) hydrogen atoms and hydrogen-like ions, as well as highly-excited helium atoms and helium-like ions. These studies were performed classically, as appropriate for Rydberg states and revealed celestial analogies, various kinds of the precession of the electron orbit and a shift of the energy. In the current paper we analyze a lithium atom or a lithium-like ion, one of the three electrons being in a Rydberg state, subjected to a laser field of high frequency. We used the generalized method of effective potentials. We showed that for a relatively small distance of the outer electron from the nucleus, the system has higher than geometrical symmetry. For an arbitrary separation of the outer electron from the nucleus, we dealt with the broken algebraic symmetry reduced to the geometrical (axial) symmetry. We describe analytically the following two outcomes for circular Rydberg states. One of the outcomes is the precession of the plane of the orbit of the highly excited electron – the precession whose frequency we calculate analytically. It leads to the following modification of the radiation spectrum: The appearance of satellites at the distances from the unperturbed frequency of the spectral line equal to multiples of the precession frequency. The other outcome is an energy shift of the Rydberg electron. Its dependence on the nuclear charge was found to be a non-monotonic function. This is a counterintuitive result.

References

Beletsky, V. V. (2001). Essays on the Motion of Celestial Bodies (1st ed.). Birkhäuser Basel. https://doi.org/10.1007/978-3-0348-8360-3
Bethe, H. A., & Salpeter, E. E. (1957). Quantum Mechanics of One- and Two-Electron Atoms (1st ed.). Springer Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-12869-5
Kapitza, P. L. (1951a). A pendulum with oscillating suspension. Uspekhi Fizicheskikh Nauk, 44(1), 7–20.
Kapitza, P. L. (1951b). Dynamic stability of a pendulum with an oscillating point of suspension. Journal of Experimental and Theoretical Physics, 21(5), 588–597.
Kryukov, N., & Oks, E. (2021). Circular Rydberg states of helium atoms or helium-like ions in a high-frequency laser field. Open Physics, 19(1), 11–17. https://doi.org/10.1515/phys-2021-0004
Nadezhdin, B. B. (1986). Radiatsionnye i Relativistskie Effekty v Atomakh i Ionakh (Radiative and Relativistic Effects in Atoms and Ions). Scientific Council of the USSR Academy of Sciences on Spectroscopy.
Nadezhdin, B. B., & Oks, E. A. (1986). A highly excited atom in the high-frequency field of linearly polarized electromagnetic radiation. Pis’ma v Zhurnal Tekhnicheskoi Fiziki, 12, 1237–1240.
Nadezhdin, B. B., & Oks, E. A. (1990). Simple quasiclassical model of heliumlike and lithiumlike ions. Optics and Spectroscopy, 68(1), 12–15.
Oks, E. (2019). Analytical Advances in Quantum and Celestial Mechanics (2nd ed.). IOP Publishing. https://doi.org/10.1088/2053-2563/ab3db0

Physics International
Volume 13 No. 1, 2022, 1-6

DOI: https://doi.org/10.3844/pisp.2022.1.6

Submitted On: 11 October 2021 Published On: 5 March 2022

How to Cite: Kryukov, N. & Oks, E. (2022).

Circular Rydberg States of Lithium Atoms or Lithium-Like Ions in a High-Frequency Laser Field: The Break of the Algebraic Symmetry

. Physics International, 13(1), 1-6. https://doi.org/10.3844/pisp.2022.1.6

  • 3,342 Views
  • 1,733 Downloads
  • 0 Citations

Download

Keywords

  • Broken Algebraic Symmetry
  • Circular Rydberg States
  • Lithium Atoms and Lithium-like Ions
  • High-Frequency Laser Field
  • Precession of the Orbital Plane
  • Energy Shift