Microwave-optical double resonance in NO2

We have observed microwave-driven inversion and recovery of the populations of the spin SUblcVelS of the chemically reactive, IIT\* triplet state ofcyclopentanone at 77,4.2, and 1.4"K. By analyzing the transients in the phosphorescence, we have extracted the values of the kinetic parameters for the

## 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

Fluorescence-detected optical-optical double resonance (OODR) spectroscopy is used to determine the rclatlve transition intensities from the 3pn CTI. r,'=O state to the n\*=6 supercomplex of NO. The results are in good agreement with the multichannel quantum defect theory analysis of Frcdin et al. (

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