The description of the smectic A and C phases and the smectic A–C phase transition of TCOOB with a diffuse-cone model

Abstract

A previous paper demonstrated that the orientational disorder present in all smectic A phases causes most molecules to make fairly large angles with the normal to the smectic plane. Thus, the molecular directions form a diffuse cone around the layer normal. It is now argued that even the preferred directions of the molecules in a smectic A phase will make a nonzero angle with the layer normal, and from the data examined, this angle, ϑ_m, appears to be about 10–15 ° for the compound TCOOB (trans‐1,4‐cyclohexane‐di‐n‐octyloxybenzoate). The smectic A‐to‐C phase transition is found to have two aspects in the diffuse‐cone model: the distribution of the molecular directions around the layer normal loses its rotational symmetry at the phase transition temperature T_A–C, and the angle ϑ_m starts increasing sharply at a temperature T_t. In most cases these two temperatures are probably equal. The increase of ϑ_m with decreasing temperature in the smectic C phase of TCOOB can be described by a (T_t−T)^0.35 dependency superimposed on a much smaller linear temperature dependency already present in the smectic A phase.