A microwave-optical double resonance spectroscopic study of TiO and TiN

Microwave-optical double-resonance signals for the N= l-2 and N= 3+4 transitions of gas-phase yttrium monoxide in its ground electronic state have been recorded. A comparison with the simulated spectrum produced using the spectroscopic parameters derived from a recent analysis of the sub-Doppler opt

## 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-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

Scvcnl mvxowwc wmsmons hz~ve been obscrvrd bctwccn hyprrfine levels m 13'Cl B %l(O+) u = 0 usmg the rcchmqur of mvzrowa\e-optlul double resonance The ICI ~3s cooled lo 3 K III a seeded supersonic e\psnsion. 3llowng c\~mirwrIon of low/ bnes. Values for the ro13Uorwi consrant.Bo = 0 085873(6) cm-', an