6533b7d8fe1ef96bd126a2b1
RESEARCH PRODUCT
Vibrational circular dichroism spectroscopy for probing the expression of chirality in mechanically planar chiral rotaxanes
C. S. ChibuezeWybren Jan BumaWybren Jan BumaValentin P. NicuMark A. J. KoenisStephen M. GoldupMichael A. JinksLucas Visschersubject
FELIX Condensed Matter PhysicsSDG 16 - PeaceMaterials scienceMechanical bond010405 organic chemistrySDG 16 - Peace Justice and Strong InstitutionsAbsolute configurationGeneral Chemistry010402 general chemistry/dk/atira/pure/sustainabledevelopmentgoals/peace_justice_and_strong_institutions01 natural sciencesJustice and Strong Institutions0104 chemical sciencesStereocenterChemistryChemical physicsCovalent bondVibrational circular dichroismMoleculeSpectroscopyChirality (chemistry)description
Mechanically interlocked molecules can exhibit molecular chirality that arises due to the mechanical bond rather than covalent stereogenic units. Developing applications of such systems is made challenging by the absence of techniques for assigning the absolute configuration of products and methods to probe how the mechanical stereogenic unit influences the spatial arrangements of the functional groups in solution. Here we demonstrate for the first time that Vibrational Circular Dichroism (VCD) can be used to not only discriminate between mechanical stereoisomers but also provide detailed information on their (co)conformations. The latter is particularly important as these molecules are now under investigation in catalysis and sensing, both of which rely on the solution phase shape of the interlocked structure. Detailed analysis of the VCD spectra shows that, although many of the signals arise from coupled oscillators isolated in the covalent sub-components, intercomponent coupling between the macrocycle and axle gives rise to several VCD bands.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-08-21 |