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Deposition of quantum dots in a capillary tube

The ability to assemble nanomaterials, such as quantum dots, enables the creation of functional devices that present unique optical and electronic properties. For instance, light-emitting diodes with exceptional color purity can be printed via the evaporative-driven assembly of quantum dots. Nevertheless, current studies of the colloidal deposition of quantum dots have been limited to the surfaces of a planar substrate. Here, we investigate the evaporation-driven assembly of quantum dots inside a confined cylindrical geometry. Specifically, we observe distinct deposition patterns, such as banding structures along the length of a capillary tube. Such coating behavior can be influenced by the evaporation speed as well as the concentration of quantum dots. Understanding the factors governing the coating process can provide a means to control the assembly of quantum dots inside a capillary tube, ultimately enabling the creation of novel photonic devices.

preprint2015arXivOpen access
Yong Lin KongFrançois BoulogneHyoungsoo KimJanine NunesJie FengHoward A. Stone
cond-mat.softcond-mat.mtrl-sci
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Yong Lin KongFrançois BoulogneHyoungsoo KimJanine NunesJie FengHoward A. Stone

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