RaX - Radium Molecules for BSM Physics
We are building a new experiment to laser cool radium-containing molecules, in collaboration with MIT (Garcia Ruiz group), Caltech (Hutzler group), and the Facility for Rare Isotope Beams (FRIB).
Why Radium?
Radium-containing molecules offer unparalleled opportunity to study some of the open questions in our understanding of the universe, such as the root cause of the observed matter/antimatter asymmetry, the long-sought search for CP violation in the strong interaction, and the potential existence of yet-undetected particles and forces [1, 2, 3]. The octuple deformation of radium nuclei [4] is predicted to amplify both parity (P) and time-reversal (T) violating nuclear properties by more than three orders of magnitude compared to stable molecules [5, 6, 7].
Recent results in the spectroscopy of radioactive molecules have demonstrated that radium-containing molecules, such as 225RaF and 225RaOH, additionally possess a relatively simple structure that is very favorable for laser cooling (see Fig. 1) [7, 8, 9]. This combination makes these molecules excellent quantum sensors for fundamental physics, opening the door to searches for P,T violating nuclear effects, such as the nuclear Schiff moment, manifesting as electric dipole moments (EDMs) of molecules [1, 2, 3].
Experimental Work
The roadmap to ultra-sensitive measurements with radium-containing molecules begins with the less radioactive isotope 226Ra (τ1/2 = 1600 yr), simplifying the experimental apparatus and molecule structure, and enabling rapid prototyping at university laboratories. To demonstrate the first laser cooling and trapping of a radioactive molecule, we will work with the well-characterized diatomic molecule 226RaF, which has an ideal molecular structure for laser cooling [9]. Concurrently, we will also test optical cycling (the key property that enables laser cooling) in 226RaOH, where the polyatomic structure generically provides parity doublets, a powerful structural advantage for state-of-the-art precision measurements [10, 11, 12, 13, 14, 15]. Fortunately, RaF and RaOH molecules have isoelectronic structure; hence sharing common production methods and similar optical transitions, accessible with common laser technologies. Many of the initial experimental breakthroughs in RaF can pave the way for advances with RaOH, and their similarity enables changing from RaF to RaOH in an experiment with the metaphorical “flip of a switch”.
References
[1] W. B. Cairncross, J. Ye, Nature Reviews Physics 1, 510–521 (Aug. 2019).
[2] R. Alarcon et al., Electric dipole moments and the search for new physics, 2022.
[3] G. Arrowsmith-Kron et al., arXiv preprint arXiv:2302.02165 (2023).
[4] Gaffney, L. P. et al., Nature 497, 199–204 (May 2013).
[5] V. Spevak, N. Auerbach, V. V. Flambaum, Physical Review C - Nuclear Physics 56, 1357–1369, arXiv: 9612044 (nucl-th) (1997).
[6] J. Dobaczewski, J. Engel, M. Kortelainen, P. Becker, Physical Review Letters 121, 232501 (23 Dec. 2018).
[7] R. F. Garcia Ruiz et al., Nature 581, 396–400 (May 2020).
[8] S. M. Udrescu et al., Phys. Rev. Lett. 127, 033001 (3 July 2021).
[9] S. M. Udrescu et al., Nature Physics 20, 202–207 (Feb. 2024).
[10] I. Kozyryev, N. R. Hutzler. Phys. Rev. Lett. 119.13 (Sept. 2017).
[11] T. S. Roussy et al., Science 381, 46–50 (2023).
[12] V. Andreev et al., Nature 562, 355–360 (Oct. 2018).
[13] L. Anderegg et al., Science 382, 665–668 (Nov. 2023).
[14] Y. Takahashi, C. Zhang, A. Jadbabaie, N. R. Hutzler, Physical Review Letters 131, 183003 (Oct. 2023).
[15] C. Zhang, P. Yu, A. Jadbabaie, N. R. Hutzler, Physical Review Letters131, 193602 (Nov. 2023).