Detection of resonant collisional radiative transfer of the vibrational energy between molecules subjected to infrared laser multiphoton excitation in a two-component medium

Resonant collisional radiative transfer of the vibrational energy between molecules subjected to infrared laser multiphoton excitation in a two-component medium has been studied. Experiments have been carried out with BCl$_3$ molecules of the natural isotopic composition in a mixture with CH$_3$F molecules, which are optically active sensitizers and acceptors of radicals. Both types of molecules resonantly absorb laser radiation. Resonant collisional radiative energy transfer from CH$_3$F molecules to $^{10}$BCl$_3$ ones has been observed. It has been shown that this process significantly increases the dissociation yield of $^{10}$BCl$_3$ and $^{11}$BCl$_3$ molecules compared to the dissociation yield with neutral acceptors of radicals. Dependences of the dissociation yields of BCl$_3$ molecules on the pump laser frequency have demonstrated a structure that closely correlates with the structure of the infrared absorption spectrum of CH$_3$F molecules. The method has been described and the experimental results have been reported. Conditions for efficient resonant collisional radiative transfer of the vibrational energy between molecules subjected to infrared laser multiphoton excitation have been discussed.