Model for atomic multiphoton ionization via Rydberg states

The efficiency of collsional ionization of escited rubidium atoms is demonstrated for \(\mathrm{Rb}^{*}-\mathrm{Kr}\) collisions Since the power required to optically saturate the Rydberg levels is much lower than for phototonization, the technique promisus to reduce the laser requrements in sungle-

Two-and three-photon resonance-enhanced multiphoton ionization spectra of the 3d Rydberg states of CS2 in the 154-160 nm region are reported. Noting that the selection rules for multiphoton transitions are quite different from those of one-photon transitions, the electronic origin of the 3dA8 Rydber

Two-color multiphoton ionization spectra of jet-cooled p-difluorobenzene due to the transitions from S, state to highly excited Rydberg states have been observed. At least six different Rydberg series of s and d characters were found. The results indicate a reduction of molecular symmetry in the Ryd

The circular to linear polarization ratio for the two-photon excitation of the \(3 s\) Rydberg states of monomethylpyridines has been measured by \(2+1\) resonant MPI spectroscopy in a static cell. The symmetry of the Rydberg vibrational bands is deduced and the results from the \(0-0\) transition s

Results of theoretical studies of rotational branching ratios and photoelectron angular distributions for (2 + 1) resonance-enhanced multiphoton ionization (REMPI) of NO via the Qz, ( 13.5) branch of the C \*H(3px) Rydberg state are reported and compared with recent measurements. Both calculated and