Collision-induced vibrational energy relaxation in 1Au glyoxal-d2

ChanSes of the rotaticnal quantum state occurring simultancousi~ (in one arr~k collision step) Edith the deactivation of \_ the torsional vibration ~7 ha%e been measured in $1 OUI IA,. Selscthe ewirarron of rotational Ie\eIs in the vibronic MeI 7' 85s accomplished by means of ;I tunable d> e laser.

Fluorescence spectn of the isotopic mixtures: glyoxnl42 -glyoxakfz were studied upon selective single-vibroniclevel excitation. It is shown that the electionic-energy transfer between isotopic species is efficient md determines the rate of the vibrational relaxation. '.

Vibrational relaxation in Dz-Kr and D a-Kr-He mivtures has been measured behind incident shock waves in the temperatUre range 1400-3500"K, and VahIes 0fPrD2\_\_He, the vibrational relaxation time of Dt infinitely dilute in one atmosphere pressure of He, are derived. These values are compared with ca

Intramolecular vibration-vibration energy transfer cross sections have beer. calculated for COz (0001) + H2,!Dz -+ COz(ll'0) + Hz/Dz,+ C02(10°0) + Hz/D\*, and-C02(20°0) + Hz/D2 based on the mechanism that the energy mismatch is transferred to the translational motion. For CO2 + Hz. the calculated cr

## The couplmg between W and VT t~ans~hons in HZ(~) + Dz(O) -Hz(l) + D2(1) and D2(2) + Hz(O) -D2(l) f Hz(L) at hl_gh colhnon energies is investigated by use of the solution of the Schrodmger equation of motion The coupling is sufficiently important that the energy exchange processes cannot be desc