Abstract
Responsive photonic crystals have been developed for chemical sensing using the variation of optical properties due to interaction with their environment1,2,3,4. Photonic crystals with tunability in the visible or near-infrared region are of interest for controlling and processing light for active components of display, sensory or telecommunication devices. Here, we report a hydrophobic blockâhydrophilic polyelectrolyte block polymer that forms a simple one-dimensional periodic lamellar structure. This results in a responsive photonic crystal that can be tuned via swelling of the hydrophilic layers by contact with a fluid reservoir. The glassy hydrophobic layer forces expansion of the hydrophilic layer along the layer normal, yielding extremely large optical tunability through changes in both layer thickness and index of refraction. Polyelectrolyte polymers are known to be highly responsive to a range of stimuli5,6. We show very large reversible optical changes due to variation of the salt concentration of a water reservoir. These one-dimensional Bragg stacks reflect incident light from the ultravioletâvisible region to the near-infrared region (λpeak=350â1,600ânm) with over a 575% change in the position of the stop band. Our work demonstrates the extremely high responsivity possible for polyelectrolyte-based photonic materials.
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Acknowledgements
We thank M. Muthukumar for useful discussions. This work was primarily supported by a grant from DARPA and further supported by a Division of Materials Research Polymer Program NSF grant DMR-0308133 and by the US Army Research Office through ISN, under contract DAAD-19-02-D-0002.
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Kang, Y., Walish, J., Gorishnyy, T. et al. Broad-wavelength-range chemically tunable block-copolymer photonic gels. Nature Mater 6, 957â960 (2007). https://doi.org/10.1038/nmat2032
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DOI: https://doi.org/10.1038/nmat2032
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