Intensity-dependent precision two-photon Doppler-free spectroscopy of Xe using narrow-bandwidth long-pulse deep-UV laser radiation

Abstract

We report on a precision measurement of the (5p)56p \, [1/2]0← (5p)6 \, 1S0 transition wavenumber of Xe by Doppler-free two-photon spectroscopy using near-Fourier-transform-limited long pulses of UV-laser radiation. The measurements led to absolute uncertainties of 750~kHz in the two-photon transition wavenumbers for the five dominant isotopes of Xe, e.g., 80118.982918(27)~cm-1 for 136Xe. These values were combined with other precision measurements in Xe to resolve an 1~GHz discrepancy between the ionization energy of Xe obtained in recent measurements from the (6 s)[3/2]2 metastable state [Herburger et al. Phys. Rev. A 109, 032816 (2024)] and the ionization energy listed in the NIST atomic database. The analysis indicates that the natural-abundance-weighted ionization energy of Xe should be revised by -0.023~cm-1 to 97833.7641(20)~cm-1. Large fluctuations in the UV-laser pulse intensities were exploited to characterize intensity-dependent shifts of the observed two-photon transition frequencies. Shifts of up to - 20~MHz were observed and attributed to frequency shifts arising from chirps in the amplification and upconversion of the laser radiation rather than to the ac-Stark effect.