KOBAYASHI-McMillan theory

Mean field theories can also be extended to the phase behavior of smectic A liquid crystal and flexible polymer blends [63, 70-74] by combining the Flory-Huggins theory for isotropic mixing and Kobayashi-McMillan theory [32, 75] for smectic A ordering of liquid crystals. 

The simple theory of the nematic-smectic A transition has been proposed by McMillan [59] (and independently by Kobayashi [60]) by extending the Maier-Saupe approach to include the possibility of translational ordering. The McMillan theory is a classical mean-field theory and therefore the free energy is given by the general Eq. (34). For the smectic A phase it can be rewritten as... 

There are several levels of approximation possible in the consideration of the NA transition. First there is the self-consistent mean field formulation due to Kobayashi and McMillan [8-10]. This is an extension to the smectic-A phase of the self-consistent mean-field formulation for nematics ( Maier-Saupe theory [11]). Kobayashi-McMillan (K-M) theory takes into account the coupling between the nematic order parameter magnitude S with a mean-field smectic order parameter. In Maier-Saupe theory, the key feature of the nematic phase - the spontaneously broken orientational symmetry - is put in by hand by making the pair potential anisotropic. In the same spirit, the K-M formulation puts in by hand a sinusoidal density modulation as well as the nematic-smectic coupling. 

McMillan proposed a simple and elegant description of smectic A by extending the Maier-Saupe theory to include an additional order parameter for characterizing the one-dimensional translational periodicity of a layered structure. A similar but somewhat more general treatment, based on the Kirkwood-Monroe theory of melting, was developed independently by Kobayashi, but McMillan s approach lends itself more easily to numerical calculations and comparison with experiment. 

The Maier-Saupe mean field theory of nematics can be extended to smectic A liquid crystals following the development of McMillan [3.24]. The smectic A phase has a unique axis (the director) like the nematic phase, but it also possesses a one-dimensional translational periodicity. The centers of mass of the molecules tend to lie on planes normal to the director. The interplanar distance, d, is approximately a molecular length, twice the molecular length or in between these two length scales. There is no positional ordering of the centers of mass of the molecules within each plane. The single-molecule potential may be deduced from the Kobayashi s pair interaction potential [3.25]... 

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