Séminaire

Mardi 19 Novembre 2024 à 11h00.

Precision Rydberg spectroscopy in few-electron atoms and molecules


Frédéric Merkt
(Frédéric Merkt)



Invité(e) par
Amanda Ross

présentera en 1 heure :

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High-resolution spectroscopic measurements in few-electron atoms and molecules are increasingly used as a means to test the foundations of the theories of atomic and molecular structure. Modern first-principles calculations of the energy-level structure of atomic and molecular systems with up to three electrons consider all interactions in the realm of the standard model of particle physics [1,2,3,4,5]. Systematic comparisons of the results of such calculations with precise spectroscopic measurements in simple atoms and molecules such as H, He, H2+, H2 and He2+ aim at searching for effects not yet included in the theory and at reducing the uncertainties of physical constants.

In this talk, I will present precision spectroscopic measurements of transitions to high Rydberg states of H, He, H2, and He2 which we use to determine precise values of their ionization energies and, in the case of H2 and He2, also of the spin-rovibrational energy-level structure of H2+ and He2+. The talk will describe our experimental strategy to overcome limitations in the precision and accuracy of the measurements originating from the Doppler effect, the Stark effect, and the laser-frequency calibration. The experimental results will then be compared with the results of first-principles calculations that include the treatment of finite-nuclear-size effects and relativistic and quantum-electrodynamics corrections up to high order in the fine-structure constant. Recent aspects of these investigations include a new determination of the Rydberg constant as a contribution to the resolution of the proton-size puzzle [6], a new method to record Doppler-free single-photon excitation spectra in the visible and the UV spectral ranges [7], and a “zero-quantum-defect” method to determine the energy-level structure of homonuclear diatomic molecular ions such as H2+ [8].

[1] E. Tiesinga, P. J. Mohr, D. B. Newell, and B. N. Taylor, Rev. Mod. Phys. 93, 025010 (2021)
[2] V. Korobov, L. Hilico and J.-Ph. Karr, Phys. Rev. Lett. 118, 233001 (2017)
[3] V. Patkos, V. A. Yerokhin, and K. Pachucki, Phys. Rev. A 103, 042809 (2021)
[4] M. Puchalski, J. Komasa, P. Czachorowski, and K. Pachucki, Phys. Rev. Lett. 122, 103003 (2019)
[5] D. Ferenc, V. I. Korobov and E. Matyus, Phys. Rev. Lett. 125, 213001 (2021)
[6] S. Scheidegger, and F. Merkt, Phys. Rev. Lett. 132, 113001 (2024)
[7] G. Clausen, S. Scheidegger, J. A. Agner, H. Schmutz, and F. Merkt, Phys. Rev. Lett. 131, 103001 (2023)
[8] I. Doran, N. Hölsch, M. Beyer, and F. Merkt, Phys. Rev. Lett. 132, 073001 (2024)

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