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Electron correlation and relativistic effects in the excited states of radium monofluoride

M. Athanasakis-Kaklamanakis, S. G. Wilkins, L. V. Skripnikov, Á. Koszorús, Alexander A. Breier, Omer F. Ahmad, M. Au, Shiwei Bai, I. Belošević, J. Berbalk, Robert Berger, Cyril Bernerd, M. L. Bissell, Anastasia Borschevsky, Alex Brinson, K. Chrysalidis, T. E. Cocolios, R. P. de Groote, A. Dorne, C. M. Fajardo-Zambrano, Robert W. Field, K. T. Flanagan, S. Franchoo, R. F. García Ruíz, Konstantin Gaul, S. Geldhof, Thomas F. Giesen, D. Hanstorp, Reinhard Heinke, Phillip Imgram, T. A. Isaev, Aleksandra A. Kyuberis, S. Kujanpää, L. Lalanne, Pierre Lassègues, Jongseok Lim, Y. C. Liu, K. M. Lynch, Abigail McGlone, Wai‐Ning Mei, G. Neyens, Miranda Nichols, L. Nies, Lukáš F. Pašteka, H. A. Perrett, A. Raggio, J. R. Reilly, S. Rothe, Erik Smets, Silviu‐Marian Udrescu, B. van den Borne, Quanjun Wang, Jessica Warbinek, J. Wessolek, X. F. Yang, Carsten Zülch

2025Nature Communications13 citationsDOIOpen Access PDF

Abstract

Highly accurate and precise electronic structure calculations of heavy radioactive atoms and their molecules are important for several research areas, including chemical, nuclear, and particle physics. Ab initio quantum chemistry can elucidate structural details in these systems that emerge from the interplay of relativistic and electron correlation effects, but the large number of electrons complicates the calculations, and the scarcity of experiments prevents insightful theory-experiment comparisons. Here we report the spectroscopy of the 14 lowest excited electronic states in the radioactive molecule radium monofluoride (RaF), which is proposed as a sensitive probe for searches of new physics. The observed excitation energies are compared with state-of-the-art relativistic Fock-space coupled cluster calculations, which achieve an agreement of ≥99.64% (within ~12 meV) with experiment for all states. Guided by theory, a firm assignment of the angular momentum and term symbol is made for 10 states and a tentative assignment for 4 states. The role of high-order electron correlation and quantum electrodynamics effects in the excitation energies is studied and found to be important for all states.

Topics & Concepts

Excited stateAtomic physicsPhysicsElectronExcitationCoupled clusterElectronic correlationAb initioRelativistic quantum chemistryElectronic structureMoleculeNuclear physicsQuantum mechanicsAtomic and Molecular PhysicsAdvanced Chemical Physics StudiesPhotocathodes and Microchannel Plates
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