Electronic Bridge processes in 229Th-doped LiCAF and LiSAF

Abstract

Electronic bridge mechanisms driving the 229Th nuclear clock transition in the vacuum-ultraviolet-transparent crystals 229Th:LiCAF (LiCaAlF6) and 229Th:LiSAF (LiSrAlF6) are investigated theoretically. Due to doping-induced symmetry breaking within the host crystal, electronic defect states emerge around the thorium nucleus and can facilitate nuclear (de)excitation via laser-assisted electronic bridge mechanisms. We investigate spontaneous and laser-assisted electronic bridge schemes for different charge compensation mechanisms. While the calculated spontaneous electronic bridge rates are very small, laser-assisted electronic bridge schemes for nuclear (de)excitation turn out to be significantly more efficient than both spontaneous nuclear decay and direct laser excitation, offering promising prospects for the future clock operation.