Electronic to vibrational energy transfer in Na(3 2P) with simple molecules

Diffcrential cross sections of thc process Na\*(3 \*P) + M(u = 0) Na(3S) + M(u') have been mcasured for several molecules: Hz, D2, Nz, 02, CO, COz, NzO, Cz H4. WC observe two different types of enerpy spectra. One of them displays il typicalIy non-resonant elcctronic to vibrational energy transfer a

The vibrational distribution of CO produced from the electronioto-vibrational energy transfer reactlon N3(3 'PI + CO(X 1 C+, u = 0) 4 Na(3 'S) + CO(X \* Z+, L) Q 8) has been determined by means of Infrared resonance absorption measurements employing a CIV CO laser. A flash-lamp-pumped dye laser is u

Collisional transfer of electronic energy from spin-orbit excited chlorine atoms, Cl\* [ ~P'(~P,,~) ] (E=882 cm-'), to vibrational energy in SOz has been observed by time-resolved infrared fluorescence from the fundamental SOI stretching levels. The rate constant ( k la) for Cl\* quenching by SO2 at

The cncrgy -rransfcr process, H&P,) f CO(O) -Hg('S~)+CO(v),hnsbccn nudisd by tie mexurcmen~oCthcLR flubrescerlce of CO. urine modulafed H&resonant radiation to excite Hg atoms. The cross section for each final vibrationallevelof v = 2 to 9 is 0.045, 0.091, 0.15, 0.17, 0.15, 0.065, 0.013, and 0.006 A

An optoacoustzc technique IS shown to gve accurate results for the extent of viirationai excltatton m electrornc-viirationai energy Qansfer. The system studied IS I(2P,,2)-Hz, and it IS shown that w&m experunental error the transfer 1s exctusively to the Ha@" = 2) viirational state. Unhke other meth