Results reported in TheJournal of Chemical Physicsintroduce an alternative path to this information, by using light to observe nuclei indirectly via the orbitingelectrons.
"We are not looking at a way to replace the conventional technique but there are a number of applications in which optical detection could provide complementary information,"says author Carlos Meriles of the City University of New York.
The new technique is based on Optical Faraday Rotation (OFR), a phenomenon in which the plane of linearly polarized light rotates upon crossing a material immersed in amagnetic field. When nuclei are sufficiently polarized, the extra magnetic field they produce is 'felt' by the electrons in the sample thus leading to Faraday rotation of their own. Because the interaction between electrons and nuclei depends on the local molecular structure, OFR-detected NMR spectroscopy provides complementary information to conventional detection.
Another interesting facet of the technique is that, unlike conventional NMR, the signal response is proportional to the sample length, but not its volume."Although we have not yet demonstrated it, our calculations show that we could magnify the signal by creating a very long optical path in a short, thin tube,"Meriles says. This signal magnification would use mirrors at both ends of a channel in a microfluidics device to reflectlaser lightrepeatedly through the sample, increasing the signal amplitude with each pass.
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