Microwave—optical double resonance in the A1A2 excited state of thioformaldehyde

Microwave-optical double resonance experiments have been carried out on the JO,, rotational levels of the 4' A'A, excited state of thioformaldehyde (HaCS). The number of microwave transitions to high rovibronic levels of the ground state observed in a given frequency range increases in a roughly lin

Pure rotntion.d transitions were observed in the electronically exited state B 3~ o+ of ICI. This state \SIS populated by optical pumping with a single-mode dye laser\_ From the observed spectrum precise rnlues of the quJdrup& h) pertine coupling constat cqQ of iodine and the effective rotational co

## Microwave -opdcal double rcsonan~~ studies have been carried out on four rotational levels of Lhe A'A, sue of rhioformaldehyde (H,CS). Several double re~~nancc signals have been observed which involve microwave transirions between levels of the excited state and high rovibronic levels of rhc gr

Fine structure and hyperfine structure information on the chemically reactive 3n~t state of cyclopentanone is obtained by the low field microwave-optical double resonance (MODOR) technique. The hvperfine structure is interpreted ter.tatively to indicate rtit the nxsnetic z asis lies perpendicular to

## Radlofrequmcy -optical double resonance is used to momtor collisional relaxation hm various J, levels in the ,&'A,, u,, = 1 state or thloformaldehyde to the 16, levels. The results indicate lhat changes of J up to +. 12 and or K, = f 2 can occur m one or at most a kw collistons. ' R-h Associalc