References
- Zakharov AV, Vakulenko AA. Director reorientation in a hybrid-oriented liquid crystal film induced by thermomechanical effect. Phys Rev E. 2009;80(3):031708-1-031708–8.
- Zakharov AV, Vakulenko AA, Iwamoto M. Nonmechanical pumping principle in sub-microsized devices. J Chem Phys. 2010;132(22):224906-1-224906–7.
- Zakharov AV, Vakulenko AA. Temperature-driven motion of liquid crystals confined in a microvolume. Phys Fluids. 2013;25(11):113101-1-113101–12.
- Zakharov AV, Vakulenko AA. Thermally excited fluid flow in a microsized liquid crystal channel with a free surface. Phys Fluids. 2015;27(6):062001-1-062001–15.
- Sliwa I, Maslennikov PV, Zakharov AV. Microfluidics of liquid crystals induced by laser radiation. Phys Rev E. 2021;103(6):062702-1-062702–10.
- Umlandt M, Kopyshev A, Pasechnik AS, et al. Light-triggered manipulations of droplets all in one: reversible wetting, transport, splitting, and merging. ACS Appl Mater Interfaces. 2022;14(36):41412–41420.
- Akopyan RS, Alaverdian RB, Santrosian EA, et al. Thermomechanical effects in the nematic liquid crystals. J Appl Phys. 2001;90(7):3371–3376.
- Hokobyan RS, Yesayan GL, Zeldovich BY. Thermomechanical oscillations in hybrid nematic liquid crystals. Phys Rev E. 2006;73(6):061701-1-061701–4.
- Zakharov AV, Vakulenko AA. Influence of the flow on the orientational dynamics induced by temperature gradient in nematic hybrid-oriented cells. J Chem Phys. 2007;127(8):084907-1-084907–7.
- Sliwa I, Zakharov AV. Nonmechanical principle for producing a flow in a homogeneously aligned microfluidic nematic channel. Eur Phys J E. 2020;43(5):29-1-29–11.
- Whitesides GM. The origins and the future of microfluidics. Nature. 2006;442(7101):368–373.
- Schoch RB, Han J, Renaud P. Transport phenomena in nanofluidics. Rev Mod Phys. 2008;80(3):839–883.
- Squires TM, Quake SR. Microfluidics: fluid physics at the nanoliter scale. Rev Mod Phys. 2005;77(3):977–1026.
- Li YW, Lee CY, Kwok HS. Liquid crystal dynamic flow control by bidirectional alignment surface. Appl Phys Lett. 2009;94(6):061111-1-061111–3.
- Eremin A, Nadasi H, Hirankittiwong P, et al. Azodendrimers as a photoactive interface for liquid crystals. Liq Cryst. 2018;45(13–15):2121–2131.
- Ericksen JL. Anisotropic fluids. Arch Ration Mech Anal. 1959;4(1):231–237.
- Leslie FM. Some constitutive equations for liquid crystals. Arch Ration Mech Anal. 1968;28(4):265–283.
- Landau LD, Lifshitz EM. Fluid mechanics. Oxford: Pergamon Press; 1987.
- Akopyan RS, Zeldovich BY. Thermomechanical effects in deformed nematics. Sov Phys JETP. 1984;60:1660–1669.
- Madhusudana NV, Ratibha RB. Elasticity and orientational order in some cyanobiphenyls: part IV. Reanalysis of the data. Mol Cryst Liq Cryst. 1982;89(1–4):249–257.
- Chmielewski AG. Viscosity coefficients of some nematic liquid crystals. Mol Chyst Liq Cryst. 1986;132(3–4):339–352.
- Marinelli M, Ghosh AK, Mercury F. Small quartz silica spheres induced disorder in octylcianobiphenyl (8CB) liquid crystals: a thermal study. Phys Rev E. 2001;63(6):061713-1-061713–9.
- Jamee P, Pitsi G, Thoen J. Systematic calorimetric investigation of the effect of silica aerosils on the nematic to isotropic transition in heptylcyanobiphenyl. Phys Rev E. 2002;66(2):021707-1-021707–8.
- Samarskij AA, Nikolaev ES. Numerical method for grid equations. Basel: Birkhauser; 1988. p. 284.
- Berezin IS, Zhidkov NP. Computing methods. 4th ed. Oxford: Pergamon Press; 1965.