Abstract
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.
Highlights
Monodisperse cholesteric liquid crystal microspheres exhibit spherically symmetric Bragg reflection, generating, via photonic cross communication, dynamically tuneable multi-coloured patterns
Cipparrone and co-workers demonstrated chiral optomechanics involving the interaction of cholesteric droplets and optical tweezers[6,7], and we recently demonstrated and explained how a new type of photonic cross communication develops between monodisperse cholesteric droplets, giving rise to intriguing multi-coloured patterns that are highly tunable[8]
Realising—due to its unique optical characteristics, the practical impossibility to copy a certain arrangement of such microspheres, and the fact that any attempt at tampering with the arrangement will likely ruin the structure—what in cryptography is known as a Physical Unclonable Function (PUF)[14,15]
Summary
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. With recent advances in microfluidic technology it has become possible to prepare large quantities of monodisperse droplets or shells of cholesterics These unusual microspheres display unique as well as highly useful optical properties thanks to the combination of spherical symmetry and optical Bragg reflection[3,4,5,6,7,8,9,10,11,12,13]. Such a quality can be used to uniquely identify an object, assuming that the response can be extracted from the object with high fidelity and represented digitally[16]
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