High-precision measurements of electric-dipole-transition amplitudes in excited states of 208Pb using Faraday rotation spectroscopy

Abstract

We have completed measurements of two low-lying excited-state electric-dipole (E1) transition amplitudes in lead. Our measured reduced matrix elements of the (6s2 6p2)3P1 (6s2 6p7s)3P0 transition at 368.3 nm and the 405.8 nm (6s2 6p2)3P2 (6s2 6p7s)3P1 transition are 1.90(1) a.u. and 3.01(2) a.u. respectively, both measured to sub-1 % precision and both in excellent agreement with the latest ab \ initio lead wavefunction calculations. These measurements were completed by comparing the low-field Faraday optical rotation spectra of each E1 transition in turn with that of the ground-state 3P0 3P1 M1 transition under identical experimental conditions. Our spectroscopy technique involves polarization modulation and lock-in detection yielding microradian-level optical rotation resolution. At temperatures where direct absorption was significant for both E1 and M1 transitions, we also extracted matrix element values from a direct optical absorption depth comparison. As part of this work we designed an interaction region within our furnace which allowed precise determination of our quartz vapor cell sample temperature to provide accurate determination of the Boltzmann thermal population of the low-lying excited states that were studied.