Acceleration of intramolecular vibrational redistribution by methyl internal rotation. A chemical timing study of p-fluorotoluene and p-fluorotoluene-d3

Abstract

Time‐integrated, frequency‐resolved fluorescence spectroscopy has been used to determine rates of intramolecular vibrational energy redistribution (IVR) from the vibrational levels 3¹ (ε_vib≊1200 cm⁻¹) and 3¹5¹ (ε_vib≊2000 cm⁻¹) in both p‐fluorotoluene and p‐fluorotoluene‐d₃ for comparison with each other and with comparable levels in p‐difluorobenzene. Methyl substitution increases the rate of IVR by roughly two orders of magnitude, while deuteration of the methyl rotor produces at most a small (two‐ to fourfold) further increase in the rate of IVR. It is argued that the IVR response to methyl substitution is a consequence of the methyl internal rotation without significant influence from the methyl vibrations. The increased IVR rate is predominantly a reflection of the large number of additional states that can couple through the exchange of energy between ring vibration and internal rotation. The difference, if any, between the protonated and deuterated methyl rotor species probably arises from subtle differences in the level structures and coupling strengths of the two systems. Fermi golden rule modeling of the relative IVR rates is built on these propositions. It accounts for much of the IVR rate increase associated with the methyl substitution as well as for the near equivalence of the –CH₃ and –CD₃ IVR rates.