University of Luxembourg, Physics &Materials Science Research Unit, L-1511 Luxembourg, Luxembourg.
University of Ljubljana, Faculty of Mathematics and Physics, Jadranska 19, SI 1000 Ljubljana, Slovenia.
Sci Rep. 2016 May 27;6:26840. doi: 10.1038/srep26840.
Monodisperse cholesteric liquid crystal microspheres exhibit spherically symmetric Bragg reflection, generating, via photonic cross communication, dynamically tuneable multi-coloured patterns. These patterns, uniquely defined by the particular sphere arrangement, could render cholesteric microspheres very useful in countless security applications, as tags to identify and authenticate their carriers, mainly physical objects or persons. However, the optical quality of the cholesteric droplets studied so far is unsatisfactory, especially after polymerisation, a step required for obtaining durable samples that can be used for object identification. We show that a transition from droplets to shells solves all key problems, giving rise to sharp patterns and excellent optical quality even after polymerisation, the polymerised shells sustaining considerable mechanical deformation. Moreover, we demonstrate that, counter to prior expectation, cross communication takes place even between non-identical shells. This opens additional communication channels that add significantly to the complexity and unique character of the generated patterns.
单分散胆甾相液晶微球呈现出球面对称布拉格反射,通过光子交叉通信产生动态可调的多色图案。这些图案由特定的球体排列唯一定义,可使胆甾相微球在无数安全应用中非常有用,例如作为标签来识别和验证其载体,主要是物理对象或人员。然而,迄今为止研究的胆甾相液滴的光学质量并不令人满意,特别是在聚合之后,聚合是获得可用于物体识别的耐用样品所必需的步骤。我们表明,从液滴到壳的转变解决了所有关键问题,即使在聚合之后也会产生清晰的图案和优异的光学质量,聚合后的壳能够承受相当大的机械变形。此外,我们证明,与之前的预期相反,即使是非相同的壳之间也会发生交叉通信。这开辟了额外的通信通道,大大增加了生成图案的复杂性和独特性。