Identification of triplet levels by Zeeman studies of microwave-optical double resonance in the à 1A2-X̃ 1A1 system of thioformaldehyde

## Microwave -optical double resonance experiments have been camed out on the 4; band of the A 'AZ-R 'At system of thioformaldehyde &CS). More than 100 microwave and radiofrequency transitions have been observed in the ii ' A2 excited state. Many of these transitions are magnetically sensitive. So

## 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

Magnetic rotation spectra of the 4; and 42 bands of the A 'AZ-z tAI system of formaldehyde+ have been photo-gapBed under high resqlution Assignments of the magnetic rotation tines have been made and the excited state rotationat kvels invoked in sin&t-tripkt perturbations have been identified. bkgnet

Magnetically tuned singlet-triplet perturbations in the 4 1 A ˜1A 2 -2 1 3 1 a ˜3A 2 system of thioformaldehyde, found in orthorotational states (I ϭ 1, the two hydrogen spins parallel) have been identified as being caused by vibronic spin-orbit coupling. This perturbation mechanism has been confirm

Doppler-limited laser-induced fluorescence excitation spectra of the origin band of the x IAl-% 'Ar system of HZCS have been recorded in zero fold and in magnetic fields up to IO kG. From analyses of the zero-tield level shifts and the profdes of magnetically sensitive lines, it is deduced that the

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