Nemato-elasticity of hybrid molecular-colloidal liquid crystals (2104.03730v1)

Abstract: Colloidal rods immersed in a thermotropic liquid-crystalline solvent are at the basis of so-called hybrid liquid crystals which are characterized by tunable nematic fluidity with symmetries ranging from conventional uniaxial nematic or anti-nematic to orthorhombic [Mundoor et al., Science 360, 768 (2018)]. We provide a theoretical analysis of the elastic moduli of such systems by considering interactions between the individual rods with the embedding solvent through surface-anchoring forces, as well as steric and electrostatic interactions between the rods themselves. For uniaxial systems the presence of colloidal rods generates a marked increase of the splay elasticity which we found to be in quantitative agreement with experimental measurements. For orthorhombic hybrid liquid crystals we provide estimates of all twelve elastic moduli and show that only a small subset of those elastic constants play a relevant role in describing the nemato-elastic properties. The complexity and possibilities related to identifying the elastic moduli in experiments are briefly discussed. The results are expected to be helpful in stimulating future studies on defect-dressed "topological" colloids and the analysis of boundary-driven phenomena where the non-trivial director topology generated by biaxial nematics plays a key role.