Intramolecular vibrational energy molecular spectroscopy

One of the main methods for investigation of the processes occurring on solid surfaces is vibrational spectroscopy in its different variants [23, 24]. As in infrared spectra, the position and the form of the observed bands depend substantially on the interaction of intramolecular vibrations with the molecular environment. In this way conclusions can be made with regard to the ways in which energy exchange occurs in the adsorbate-solid surface system. Several mechanisms for dissipation of vibrational energy of adsorbed molecules are considered [25-30] ... 

In sharp contrast to conventional spectroscopic methods based on direct mie-photon absorption, IRMPD spectroscopy relies on the sequential absorption of a large number of IR photons. This excitation mechanism leaves an imprint on the observed IR spectrum in the sense that vibrational bands are typically broadened, red-shifted and affected in relative intensity to some extent. While the intramolecular processes underlying these spectral modifications have been addressed and qualitatively modelled in a large number of studies [166-172], it is often hard to predict quantitatively an IRMPD spectrum because the required molecular parameters, in particular the anharmonic couplings between vibrational normal modes at high internal energies, are usually unknown and cannot be calculated accurately using current quantum-chemical methods, fri practice, most experimental IRMPD spectra are therefore analysed oti the basis of computed linear absorption spectra, which usually provide a reasonable approximation to the IRMPD spectrum. 

The main applications covered in this study are the accurate determination of rotation and rotation-vibration molecular energies the determination of the molecular geometry of simple molecules the evaluation of force field and of the vibration- and rotation-vibration interactions the measurement of pressure broadening and pressure shift of the spectral lines the determination of electric dipole moments via laser-Stark spectroscopy the studies of intramolecular dynamics the calculation of rate constants, equilibrium constants and other thermodynamic data the evaluation of relaxation times. 

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