On the Feasibility of Rovibrational Laser Cooling of Radioactive RaF+ and RaH+ Cations

Timur A Isaev,Michail Athanasakis-Kaklamanakis,Shane G Wilkins

doi:10.3390/atoms9040101

Timur A Isaev, Michail Athanasakis-Kaklamanakis + Show 1 more

Open Access

https://doi.org/10.3390/atoms9040101

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Journal: Atoms	Publication Date: Nov 26, 2021
Citations: 1	License type: CC BY 4.0

Affiliation: European Organization for Nuclear Research, KU Leuven

Abstract

Polar radioactive molecules have been suggested to be exceptionally sensitive systems in the search for signatures of symmetry-violating effects in their structure. Radium monofluoride (RaF) possesses an especially attractive electronic structure for such searches, as the diagonality of its Franck-Condon matrix enables the implementation of direct laser cooling for precision experiments. To maximize the sensitivity of experiments with short-lived RaF isotopologues, the molecular beam needs to be cooled to the rovibrational ground state. Due to the high kinetic energies and internal temperature of extracted beams at radioactive ion beam (RIB) facilities, in-flight rovibrational cooling would be restricted by a limited interaction timescale. Instead, cooling techniques implemented on ions trapped within a radiofrequency quadrupole cooler-buncher can be highly efficient due to the much longer interaction times (up to seconds). In this work, the feasibility of rovibrationally cooling trapped RaF+ and RaH+ cations with repeated laser excitation is investigated. Due to the highly diagonal nature between the ionic ground state and states in the neutral system, any reduction of the internal temperature of the molecular ions would largely persist through charge-exchange without requiring the use of cryogenic buffer gas cooling. Quasirelativistic X2C and scalar-relativistic ECP calculations were performed to calculate the transition energies to excited electronic states and to study the nature of chemical bonding for both RaF+ and RaH+. The results indicate that optical manipulation of the rovibrational distribution of trapped RaF+ and RaH+ is unfeasible due to the high electronic transition energies, which lie beyond the capabilities of modern laser technology. However, more detailed calculations of the structure of RaH+ might reveal possible laser-cooling pathways.

Highlights

The high-precision spectroscopy of atomic and molecular beams within reverting electromagnetic fields has emerged as a highly sensitive technique to search for physics beyond the Standard Model, potentially probing energy scales a few orders of magnitude greater than the capabilities of state-of-the-art particle colliders [1]
The structure of the diatomic Radium monofluoride (RaF) molecule has been proposed as especially attractive for tabletop experiments that probe the extent of fundamental symmetry violations in the universe [2,3], owing to its enhanced sensitivity to symmetry-violating effects within the radium nucleus [4,5] and the highly diagonal Franck-Condon matrix for vibronic transitions between the ground and low-lying excited electronic states that allow for direct laser cooling [6]
The technique of Isotope Separation On-Line (ISOL) at the ISOLDE radioactive ion beam (RIB) facility at CERN was combined with Collinear Resonance Ionization Spectroscopy (CRIS) [7] to measure the vibronic spectra of short-lived 223−226,228 RaF molecules

Summary

Introduction

The high-precision spectroscopy of atomic and molecular beams within reverting electromagnetic fields has emerged as a highly sensitive technique to search for physics beyond the Standard Model, potentially probing energy scales a few orders of magnitude greater than the capabilities of state-of-the-art particle colliders [1].The structure of the diatomic RaF molecule has been proposed as especially attractive for tabletop experiments that probe the extent of fundamental symmetry violations in the universe [2,3], owing to its enhanced sensitivity to symmetry-violating effects within the radium nucleus [4,5] and the highly diagonal Franck-Condon matrix for vibronic transitions between the ground and low-lying excited electronic states that allow for direct laser cooling [6].Recently, a milestone in the study of compounds of short-lived nuclei was achieved, with the first laser-spectroscopic study of RaF molecules containing different isotopes ofRa [6]. The technique of Isotope Separation On-Line (ISOL) at the ISOLDE radioactive ion beam (RIB) facility at CERN was combined with Collinear Resonance Ionization Spectroscopy (CRIS) [7] to measure the vibronic spectra of short-lived 223−226,228 RaF molecules. To maximize the precision of such experiments, the most developed of which are searching for small variations in the coherent precession of electrons within the internal molecular fields, the molecular beam should exist entirely in a single rovibrational state. In this case, the experimental count rate is maximized without needing to compromise the spectroscopic resolution

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