Importance
of C*–H Based Modes and Large Amplitude
Motion Effects in Vibrational Circular Dichroism Spectra: The Case
of the Chiral Adduct of Dimethyl Fumarate and Anthracene
posted on 2014-06-19, 00:00authored byMarco Passarello, Sergio Abbate, Giovanna Longhi, Susan Lepri, Renzo Ruzziconi, Valentin Paul Nicu
The role played by the C*–H
based modes (C* being the chiral
carbon atom) and the large amplitude motions in the vibrational absorption
(VA) and vibrational circular dichroism (VCD) spectra is investigated.
The example of an adduct of dimethyl fumarate and anthracene, i.e.,
dimethyl-(+)-(11R,12R)-9,10-dihydro-9,10-ethanoanthracene-11,12-dicarboxylate,
and two deuterated isotopomers thereof specially synthesized for this
goal, are considered. By comparing the experimental and DFT calculated
spectra of the undeuterated and deuterated species, we demonstrate
that the C*–H bending, rocking, and stretching modes in the
VA and VCD spectra are clearly identified in well defined spectroscopic
features. Further, significant information about the conformer distribution
is gathered by analyzing the VA and VCD data of both the fingerprint
and the C–H stretching regions, with particular attention paid
to the band shape data. Effects related to the large amplitude motions
of the two methoxy moieties have been simulated by performing linear
transit (LT) calculations, which consists of varying systematically
the relative positions of the two methoxy moieties and calculating
VCD spectra for the partially optimized structures obtained in this
way. The LT method allows one to improve the quality of calculated
spectra, as compared to experimental results, especially in regard
to relative intensities and bandwidths.