posted on 2019-12-03, 19:50authored byAndrew
J. Schmitz, Hari Datt Pandey, Farzaneh Chalyavi, Tianjiao Shi, Edward E. Fenlon, Scott H. Brewer, David M. Leitner, Matthew J. Tucker
From guiding chemical reactivity in synthesis or protein
folding
to the design of energy diodes, intramolecular vibrational energy
redistribution harnesses the power to influence the underlying fundamental
principles of chemistry. To evaluate the ability to steer these processes,
the mechanism and time scales of intramolecular vibrational energy
redistribution through aromatic molecular scaffolds have been assessed
by utilizing two-dimensional infrared (2D IR) spectroscopy. 2D IR
cross peaks reveal energy relaxation through an aromatic scaffold
from the azido- to the cyano-vibrational reporters in para-azidobenzonitrile (PAB) and para-(azidomethyl)benzonitrile
(PAMB) prior to energy relaxation into the solvent. The rates of energy
transfer are modulated by Fermi resonances, which are apparent by
the coupling cross peaks identified within the 2D IR spectrum. Theoretical
vibrational mode analysis allowed the determination of the origins
of the energy flow, the transfer pathway, and a direct comparison
of the associated transfer rates, which were in good agreement with
the experimental results. Large variations in energy-transfer rates,
approximately 1.9 ps for PAB and 23 ps for PAMB, illustrate the importance
of strong anharmonic coupling, i.e., Fermi resonance, on the transfer
pathways. In particular, vibrational energy rectification is altered
by Fermi resonances of the cyano- and azido-modes allowing control
of the propensity for energy flow.