TaN, a molecular system for probing P,T-violating hadron physics

Abstract

All-electron configuration interaction theory in the framework of the Dirac-Coulomb Hamiltonian has been applied to the TaN molecule, a promising candidate in the search for Beyond-Standard-Model physics in both the hadron and the lepton sector of matter. We obtain in the first excited 31 state a P,T-odd effective electric field of 36.0 [ GV cm], a scalar-pseudoscalar P,T-odd interaction constant of 32.8 [kHz], and a nuclear magnetic-quadrupole moment interaction constant of 0.74 [1033 Hze\, cm2]. The latter interaction constant has been obtained with a new approach which we describe in detail. Using the same highly correlated all-electron wavefunctions with up to 2.5 billion expansion terms, we obtain a parallel magnetic hyperfine interaction constant of -2954 [MHz] for the 181Ta nucleus, a very large molecule-frame electric dipole moment of -4.91 [Debye], and spectroscopic constants for the four lowest-lying electronic states of the molecule.