Molecular enhancement factors for P, T-violating eEDM in BaCH3 and YbCH3 symmetric top molecules

Abstract

High-precision tests of fundamental symmetries are looking for the parity- (P), time-reversal- (T) violating electric dipole moment of the electron (eEDM) as proof of physics beyond the Standard Model. Particularly, in polyatomic molecules, the complex vibrational and rotational structure gives the possibility to reach high enhancement of the P, T-odd effects in moderate electric fields. Additionally, it is possible to increase the statistical sensitivity by using laser cooling. In this work, we calculate the P, T-odd electronic structure parameters Wd and Ws for the promising candidates BaCH3 and YbCH3 for the interpretation of future experiments. We employ high-accuracy relativistic coupled cluster methods and systematically evaluate the uncertainties of our computational approach. Compared to other Ba- and Yb-containing molecules, BaCH3 and YbCH3 exhibit larger Wd and Ws associated to increased covalent character of the M--C bond. The calculated values are 3.22 0.11 × 1024hHzecm and 13.80 0.35 × 1024hHzecm for Wd, and 8.420.29~hkHz and 45.351.15~hkHz for Ws, in BaCH3 and YbCH3, respectively. The robust, accurate, and cost-effective computational scheme reported in this work makes our results suitable for extracting the relevant fundamental properties from future measurements and also can be used to explore other polyatomic molecules sensitive to various violations of fundamental symmetries.