Precision lifetime measurements of Cs 6p2P1/2and 6p2P3/2levels by single-photon counting

Abstract

Time-correlated single-photon counting is used to measure the lifetimes of the 6p ${}_{}{}^2{}_{}{}^{}$ ${\mathit{P}}_{1/2}$ and 6p ${}_{}{}^2{}_{}{}^{}$ ${\mathit{P}}_{3/2}$ levels in atomic Cs with accuracies ≊0.2–0.3 %. A high-repetition-rate, femtosecond, self-mode-locked Ti:sapphire laser is used to excite Cs produced in a well-collimated atomic beam. The time interval between the excitation pulse and the arrival of a fluorescence photon is measured repetitively until the desired statistics are obtained. The lifetime results are 34.75(7) and 30.41(10) ns for the 6p ${}_{}{}^2{}_{}{}^{}$ ${\mathit{P}}_{1/2}$ and 6p ${}_{}{}^2{}_{}{}^{}$ ${\mathit{P}}_{3/2}$ levels, respectively. These lifetimes fall between those extracted from ab initio many-body perturbation-theory calculations by Blundell, Johnson, and Sapirstein [Phys. Rev. A 43, 3407 (1991)] and V. A. Dzuba et al. [Phys. Lett. A 142, 373 (1989)] and are in all cases within 0.9% of the calculated values. The measurement errors are dominated by systematic effects, and methods to alleviate these and to approach an accuracy of 0.1% are discussed. The technique is a viable alternative to the fast-beam laser approach for measuring lifetimes with extreme accuracy.