Rayleigh-B\'enard convection in a homeotropically aligned nematic liquid crystal
Abstract
We report experimental results for convection near onset in a thin layer of a homeotropically aligned nematic liquid crystal heated from below as a function of the temperature difference T and the applied vertical magnetic field H and compare them with theoretical calculations. The experiments cover the field range 8 h H/ HF 80 (HF = is the Fr\'eedericksz field). For h less than a codimension-two field hct 46 the bifurcation is subcritical and oscillatory, with travelling- and standing-wave transients. Beyond hct the bifurcation is stationary and subcritical until a tricritical field ht= 57.2 is reached, beyond which it is supercritical. The bifurcation sequence as a function of h found in the experiment confirms the qualitative aspects of the theoretical predictions. However, the value of hct is about 10% higher than the predicted value and the results for kc are systematically below the theory by about 2% at small h and by as much as 7% near hct. At hct, kc is continuous within the experimental resolution whereas the theory indicates a 7% discontinuity. The theoretical tricritical field htth = 51 is somewhat below the experimental one. The fully developed flow above Rc for h < hct is chaotic. For hct < h < ht the subcritical stationary bifurcation also leads to a chaotic state. The chaotic states persist upon reducing the Rayleigh number below Rc, i.e. the bifurcation is hysteretic. Above the tricritical field ht, we find a bifurcation to a time independent pattern which within our resolution is non-hysteretic.
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