Abstract
Rational control over the morphology and the functional properties of inorganic nanostructures has been a long-standing goal in the development of bottom-up device fabrication processes. We report that the geometry of hydrothermally grown zinc oxide nanowires1,2,3,4 can be tuned from platelets to needles, covering more than three orders of magnitude in aspect ratio (~0.1–100). We introduce a classical thermodynamics-based model to explain the underlying growth inhibition mechanism by means of the competitive and face-selective electrostatic adsorption of non-zinc complex ions at alkaline conditions. The performance of these nanowires rivals that of vapour-phase-grown nanostructures5,6, and their low-temperature synthesis (<60 °C) is favourable to the integration and in situ fabrication of complex and polymer-supported devices7,8,9. We illustrate this capability by fabricating an all-inorganic light-emitting diode in a polymeric microfluidic manifold. Our findings indicate that electrostatic interactions in aqueous crystal growth may be systematically manipulated to synthesize nanostructures and devices with enhanced structural control.
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Acknowledgements
This research was funded by the Center for Bits and Atoms (NSF CCR0122419) and the MIT Media Lab. We thank S. Manalis, V. Bulovic, and A. Belcher for generously providing use of equipment. The authors acknowledge the partial support of the Korea Foundation for Advanced Studies (awarded to J.J.) and Samsung (research internship to J.J.); the Harvard Society of Fellows (awarded to M.P.); and the Wallace H. Coulter Early Career Award, NARSAD Young Investigator Award, NSF, and NIH Director’s New Innovator Award (awarded to E.S.B.).
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J.J. and B.Y.C. designed all the experiments. J.J. conducted all the experiments. B.Y.C. assisted with device fabrication, microfluidics, and spectroscopy. M.P. assisted with microfluidics. All authors contributed to data analysis and writing of the manuscript.
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Joo, J., Chow, B., Prakash, M. et al. Face-selective electrostatic control of hydrothermal zinc oxide nanowire synthesis. Nature Mater 10, 596–601 (2011). https://doi.org/10.1038/nmat3069
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DOI: https://doi.org/10.1038/nmat3069
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