Investigation of Phase Transitions in Nematic Liquid Crystals by Fractional Calculation
Year 2018,
, 373 - 377, 28.12.2018
Müjde Durukan Gültepe
,
Zekai Tek
Abstract
In
this study, we investigate nematic-isotropic phase transitions in liquid
crystals using fractionally generalized form of the Maier-Saupe Theory (MST).
MST is one of the mean-field theories commonly used in the nematic liquid
crystals which proved to be extremely useful in explaining nematic-isotropic
phase transitions. Fractionally obtained results compared with those of the
experimental data for p-azoxyanisole (PAA) in the literature. In this context,
the dependence of fourth rank order parameters on second rank order parameters
is handled by being a measure of fractality of space. It is observed that the
variation of second-rank and fourth rank order parameters versus temperature
are in accordance with some values of fractal dimensions. As a result, we can
conclude that there is a close relationship between temperature and fractional derivative
order parameters.
References
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Year 2018,
, 373 - 377, 28.12.2018
Müjde Durukan Gültepe
,
Zekai Tek
References
- 1. Andrade, R,F, S, Remarks on the behavior of the ising chain in the generalized statistics, Physica A: Statistical Mechanics and its Applications, 1994, 203, 486-494.
- 2. Ramshaw, J, D, Irreversibility and generalized entropies, Physics Letters A, 1993, 175 (3-4), 171.
- 3. Ertik, H, Demirhan, D, Şirin, H, Büyükkılıc, F, A fractional mathematical approach to the distribution functions of quantum gases: Cosmic microwave background radiation problem is revisited, Physica A: Statistical Mechanics and its Applications, 2009, 388 (21), 4573-4585.
- 4. Ertik, H, Demirhan, D, Şirin, H, Büyükkılıc, F, Time fractional development of quantum systems, Journal of Mathematical Physics, 2010, 51 (8), 082102.
- 5. Ubriano, M, R, Entropies based on fractional calculus, Physics Letters A, 2009, 373, 2516-2519.
- 6. Hamley, I, W, Garnett, S, Luckhurst, G, R, Roskilly, S, J, Sedon, J, M, Pedersen, S, Richardson, R, M, Orientational ordering in the nematic phase of a thermotropic liquid crystal: A small angle neutron scattering study, The Journal of Chemical Physics, 1996, 104, 10046.
- 7. Tarasov, V, E, Fractional hydrodynamic equations for fractal media, Annals of Physics, 2005, 318:286-307.
- 8. Tsallis, C, Mendes, R, S, Plastino, A, R, The role of contraints within generalized non extensive statistics, Physica A: Statistical Mechanics and its Applications, 1998, 261, 534-554.
- 9. Metzler, R, Kalfter, J, The random walk’s guide to anomalous diffusion: a fractional approach, Physics Reports, 2000, 339:1-77.
- 10. Biyajima, M, Mizoguchi, T, Suzuki, N, New blackbody radiation low based on fractional calculus and its application to nasa cobe data, Physica A, 2015, 440, 129-138.
- 11. Gabano, J, D, Poinot, T, Kanoun, H, LPV Continuous fractional modeling applied to ultracapacitor impedance identification, Control Engineering Practice, 2015, 45, 86-97.
- 12. Sun, H, Zhang, Y, Baleanu, D, Chen, W, Chen, Y, A new collection of real world applications of fractional calculus işn science and engineering, Commun Nonliear Sci Numer Simulat, 2018, 213-231.
- 13. Hilfer, R, Applications of fractional calculus in physics, World Scientific, 2000, 463p.
- 14. Oldham, K, B, Spainer, J, The fractional calculus, Academic Press, San Diego, 1974, pp 234.
15. Podlubny, I, Fractional differential equations, Academic Press: San Diego, 1999, pp 340.
- 16. Saupe, A, Recent results in the field of liquid crystals, Angew. Chem. International Edittion, England, 1968, vol. 7, pp 97-112.
- 17. Maier, W, Saupe, A, Naturforsch, Z, A simple molecular statistical theory of the nematic crystalline-liquid phase II, 1960, 15a, pp 287.