Ultrafast collisional redistribution of vibrational energy in small polyatomic molecules

Vibrational energy relaxation and vibrational cooling of polyatomic liquids were studied with the ultrafast infrared-Raman (IR-Raman) technique. In the IR-Raman technique, a type of two-dimensional vibrational spectroscopy, a vibrational transition is pumped with a mid-infrared pulse and the instant

Individual Ctf-~-strctchmg modes wcrc. cxcltcd by single tunable infrared pu!scs. l'hc gcncratcd cxccs population of the rnolcculcb was monitored by subscqucnt probe pulccs usmg spontaneous anti-Stokes R~mm scat Wing. ~xpcrirnental ddta JTL' xcported on ethanol &and CHsI iu solutions of CC1 4, Very

A thermodynamic Green's function technique is successfully applied to the calculation of IVR rates of polyatonfic molecul, The energy dependence of IVR rates has interesting threshold features: rates are zero below some critical energy Ec, aJ non-zero for higher energies. This dependence can be unde

The rates of vibrational energy decay for the S2 excited state of azulene have been measured in both monatomic and polyatomic matrix media at 4 K. We find that the existence of molecular modes in the polyatomic matrix does not substantially affect the rate of energy decay within the S1 vibrational m