6533b823fe1ef96bd127e238
RESEARCH PRODUCT
Measuring molecular parity nonconservation using nuclear-magnetic-resonance spectroscopy
Mikhail KozlovJohn W. BlanchardDmitry BudkerLykourgos BougasJames EillsJames EillsAlexander PinesAlexander Pinessubject
Chemical Physics (physics.chem-ph)PhysicsGeneral PhysicsChemical shiftphysics.chem-phFOS: Physical sciencesParity (physics)Nuclear magnetic resonance spectroscopyWeak interaction010402 general chemistry01 natural sciencesSpectral lineMathematical Sciences0104 chemical sciences3. Good healthPhysics - Chemical Physics0103 physical sciencesPhysical SciencesChemical SciencesPhysics::Atomic PhysicsAtomic physicsEnantiomer010306 general physicsEnantiomeric excessChirality (chemistry)description
The weak interaction does not conserve parity and therefore induces energy shifts in chiral enantiomers that should in principle be detectable in molecular spectra. Unfortunately, the magnitude of the expected shifts are small and in spectra of a mixture of enantiomers, the energy shifts are not resolvable. We propose a nuclear magnetic resonance (NMR) experiment in which we titrate the chirality (enantiomeric excess) of a solvent and measure the diasteriomeric splitting in the spectra of a chiral solute in order to search for an anomalous offset due to parity nonconservation (PNC). We present a proof-of-principle experiment in which we search for PNC in the \textsuperscript{13}C resonances of small molecules, and use the \textsuperscript{1}H resonances, which are insensitive to PNC, as an internal reference. We set a new constraint on molecular PNC in \textsuperscript{13}C chemical shifts at a level of $10^{-5}$\,ppm, and provide a discussion of important considerations in the search for molecular PNC using NMR spectroscopy.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2017-10-30 |