Manipulating Magneto-Optic Properties of a Chiral Polymer by Doping with Stable Organic Biradicals

We report the first example of tuning the large magneto-optic activity of a chiral polymer by addition of stable organic biradicals. The spectral dispersion of Verdet constant, which quantifies magneto-optic response, differs substantially between the base polymer and the nanocomposite. We employed...

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Veröffentlicht in:Nano letters 2016-09, Vol.16 (9), p.5451-5455
Hauptverfasser: Lim, Chang-Keun, Cho, Min Ju, Singh, Ajay, Li, Qi, Kim, Won Jin, Jee, Hong Sub, Fillman, Kathlyn L, Carpenter, Stephanie H, Neidig, Michael L, Baev, Alexander, Swihart, Mark T, Prasad, Paras N
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Sprache:eng
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Zusammenfassung:We report the first example of tuning the large magneto-optic activity of a chiral polymer by addition of stable organic biradicals. The spectral dispersion of Verdet constant, which quantifies magneto-optic response, differs substantially between the base polymer and the nanocomposite. We employed a microscopic model, supported by atomistic calculations, to rationalize the behavior of this nanocomposite system. The suggested mechanism involves magnetic coupling between helical conjugated polymer fibrils, with spatially delocalized helical π-electron density, and the high density of spin states provided by the biradical dopants, which leads to synergistic enhancement of magneto-optic response. Our combined experimental and theoretical studies reveal that the manipulation of magnetic coupling in this new class of magneto-optic materials offers an opportunity to tailor the magnitude, sign, and spectral dispersion of the Verdet constant over a broad range of wavelengths, from the UV to the near-IR. This provides a new strategy for creating conformable materials with extraordinary magneto-optic activity, which can ultimately enable new applications requiring spatially and temporally resolved measurement of extremely weak magnetic fields. In particular, magneto-optic materials, presently employed in technologies like optical isolators and optical circulators, could be used in ultrasensitive optical magnetometers. This, in turn, could open a path toward mapping of brain activity via optical magnetoencephalography.
ISSN:1530-6984
1530-6992
DOI:10.1021/acs.nanolett.6b01874