CO2 laser assisted vibrational overtone spectroscopy

Abstract

We report the implementation of a new spectroscopic scheme for measuring vibrational overtone spectra of molecules in collisionless environments. This approach is based upon selective infrared multiphoton dissociation (IRMPD) of molecules that have undergone a light atom stretch vibrational overtone transition. Overtone excitation is ultimately monitored by laser induced fluorescence (LIF) detection of the dissociation products. Application of this technique to measure the 5←0 OH stretch transition methanol at 50 m Torr produces an excitation spectrum which is virtually identical to a photoacoustic spectrum recorded at 40 Torr, indicating that the former faithfully represents the vibrational overtone absorption. When applied to methanol cooled in a supersonic expansion, this method results in considerable simplification of the 5ν_OH vibrational overtone spectrum and reveals the presence of a strong Fermi resonance which divides the 5ν_OH oscillator strength equally between two vibrational levels. This new spectroscopic technique should permit the application of supersonic expansion and double resonance techniques to vibrational overtone spectroscopy of a wide variety of molecules.