High-precision measurement and ab initio calculation of the (6s26p2)\,3\!P0 → \, 3\!P2 electric quadrupole transition amplitude in 208Pb

Abstract

We have completed a measurement of the (6s26p2)\, 3\!P0 → \, 3\!P2 939 nm electric quadrupole (E2) transition amplitude in atomic lead. Using a Faraday rotation spectroscopy technique and a sensitive polarimeter, we have measured this very weak E2 transition for the first time, and determined its amplitude to be 3\!P2 || Q || 3\!P0 = 8.91(9) a.u.. We also present an ab initio theoretical calculation of this matrix element, which agrees with experiment at the 0.5\% level. We heat a quartz vapor cell containing 208Pb to between 800 and 940 C, apply a \! 10 \, G longitudinal magnetic field, and use polarization modulation/lock-in detection to measure optical rotation amplitudes of order 1 mrad with noise near 1 μrad. We compare the Faraday rotation amplitude of the E2 transition to that of the 3\!P0 -\, 3\!P1 1279 nm magnetic dipole (M1) transition under identical sample conditions.