Theoretical and real-time study of uniaxial nematic liquid crystal phase transitions using Fresnel diffraction
Liquid crystals (LCs) play a fundamental and significant role in modern technology. Recently, they have also been used in active switching, adaptive optics, and next-generation displays for augmented and virtual reality. This is due to the diverse properties of their various phases and the growing p...
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Zusammenfassung: | Liquid crystals (LCs) play a fundamental and significant role in modern
technology. Recently, they have also been used in active switching, adaptive
optics, and next-generation displays for augmented and virtual reality. This is
due to the diverse properties of their various phases and the growing physical
understanding of LCs. Our goal is to examine the applicability of a new method
in determining these quantities for thermotropic uniaxial nematic liquid
crystals (NLCs), even though nearly all theoretical and experimental efforts
are focused on a deeper understanding of the temperature-dependent free energy
behavior and other quantities related to it, especially in the vicinity of the
first- and second-order phase transitions of LCs. The method that is being
discussed is based on Fresnel diffraction (FD) from phase objects, which has
found a wide range of precise metrological applications over the past two
decades. Diffractometry is a very sensitive, accurate, and immune technique
that can convert any change in the order of LCs as a function of temperature
into a change in the optical phase and, as a result, a recordable change in the
visibility of the light diffraction pattern from phase steps. This contrasts
with interferometry, which is very sensitive to environmental changes.
Theoretical investigations, numerical calculations, and comparisons of the
results with experimental observations in turn demonstrate very high compliance
with the output of other existing methods. As we will see, this method has the
potential to not only strengthen existing approaches by addressing some of
their flaws and shortcomings but also to take its place next to them. |
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DOI: | 10.48550/arxiv.2208.07944 |