The vibrational relaxation of some internal and external phonons in crystal SO2 as a function of temperature is reported and discussed in terms of depopulation and/or dephasing decay mechanisms. By picosecond CARS spectroscopy the lifetime of the polar ω1 (A1) mode (symmetric stretching) was studied in the temperature range 35–170 K. High-resolution Raman spectroscopy was used to measure the linewidth of the second Davydov component, ω1 (A2), and of lattice modes at 76 and 102 cm −1 in the same temperature range. The experimental data are analyzed on the basis of current theories on vibrational decay in molecular crystals. Using a recently proposed intermolecular potential for crystal SO2 including atom-atom and electrostatic interactions, the contributions to linewidth from third-order depopulation processes were calculated. In the case of lattice phonons, the calculated bandwidths are in good agreement with experimental results at low temperature. At higher temperature fourth-order decay mechanisms become efficient. As to the internal phonons, calculations show that depopulation has negligible importance for decay. Higher-order contributions to linewidth must be considered in this case. We have estimated the four-phonon intraband scattering and we have found that this mechanism is mostly responsible for the observed behaviour with temperature. It is suggested that fourth-order intraband processes may be important also for the decay of other well isolated phonons in molecular crystals.
Vibrational relaxation in crystal SO2 / P.Procacci;A.Tafi;L.Angeloni;R.Righini;P.Salvi. - In: CHEMICAL PHYSICS. - ISSN 0301-0104. - STAMPA. - 154:(1991), pp. 331-342.
Vibrational relaxation in crystal SO2
PROCACCI, PIERO;ANGELONI, LEONARDO;RIGHINI, ROBERTO;SALVI, PIER REMIGIO
1991
Abstract
The vibrational relaxation of some internal and external phonons in crystal SO2 as a function of temperature is reported and discussed in terms of depopulation and/or dephasing decay mechanisms. By picosecond CARS spectroscopy the lifetime of the polar ω1 (A1) mode (symmetric stretching) was studied in the temperature range 35–170 K. High-resolution Raman spectroscopy was used to measure the linewidth of the second Davydov component, ω1 (A2), and of lattice modes at 76 and 102 cm −1 in the same temperature range. The experimental data are analyzed on the basis of current theories on vibrational decay in molecular crystals. Using a recently proposed intermolecular potential for crystal SO2 including atom-atom and electrostatic interactions, the contributions to linewidth from third-order depopulation processes were calculated. In the case of lattice phonons, the calculated bandwidths are in good agreement with experimental results at low temperature. At higher temperature fourth-order decay mechanisms become efficient. As to the internal phonons, calculations show that depopulation has negligible importance for decay. Higher-order contributions to linewidth must be considered in this case. We have estimated the four-phonon intraband scattering and we have found that this mechanism is mostly responsible for the observed behaviour with temperature. It is suggested that fourth-order intraband processes may be important also for the decay of other well isolated phonons in molecular crystals.
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