A unified view on the rotational symmetry of equilibiria of nematic polymers, dipolar nematic polymers, and polymers in higher dimensional space

Abstract: Abstract. We study equilibrium states of the Smoluchowski equation for rigid, rod-like polymer ensembles. We start with several cases in the three dimensional space: a) nematic polymers where the only intermolecular interaction is the excluded volume effect, modeled using the Maier-Saupe potential, b) dipolar nematic polymers where the intermolecular interaction consists of the dipoledipole potential and the Maier-Saupe potential, c) dipolar nematic polymers in the presence of a stretching elongational flow, a… Show more

“…As η increases, G ηAΩ shows increasing order evidenced by the increase of the order parameter S 2 . Now, we have the following This proposition is a consequence of the result of Wang and Hoffman [56] which will be recalled in Section 4. With this, we formulate the following conjecture, which has been verified in dimension n = 2 [28], n = 3 [1,29,47,48] and n = 4 [31].…”

“…Indeed, we anticipate that only stable equilibria can lead to a long time dynamics described by hydrodynamic equations. First, we should note that local equilibria are known in any dimension n [56] (see also [15,28,49] for the case n = 2 and [1,14,29,47,48,61,63] for the case n = 3). However, the stability of these equilibria is not known for general dimension n but only for n = 2 [28], n = 3 [1,29,47,48] and n = 4 [31].…”

“…To complete the characterization of the equilibria, we need to solve the compatibility equation (78). As pointed out above, this has been done in any dimension n in [56] (see also [49] for n = 2 and [1,29,47,48,63] for n = 3). This result is summarized without proof in the following lemma Lemma 4.4 (Final characterization of the equilibria [56]).…”

“…As pointed out above, this has been done in any dimension n in [56] (see also [49] for n = 2 and [1,29,47,48,63] for n = 3). This result is summarized without proof in the following lemma Lemma 4.4 (Final characterization of the equilibria [56]). Let f be an an equilibrium.…”

“…1b). In all cases, the equation ρ n (λ) = ρ has a solution if and only if ρ ≥ ρ * and this solution is unique in the case n = 2 while, in the case n ≥ 3, there are two solutions if ρ ∈ (ρ * , ρ n (0)], and one solution if ρ ∈ {ρ * } ∪ (ρ n (0), ∞) (see [56] for details).…”

From kinetic to fluid models of liquid crystals by the moment method

“…As η increases, G ηAΩ shows increasing order evidenced by the increase of the order parameter S 2 . Now, we have the following This proposition is a consequence of the result of Wang and Hoffman [56] which will be recalled in Section 4. With this, we formulate the following conjecture, which has been verified in dimension n = 2 [28], n = 3 [1,29,47,48] and n = 4 [31].…”

“…Indeed, we anticipate that only stable equilibria can lead to a long time dynamics described by hydrodynamic equations. First, we should note that local equilibria are known in any dimension n [56] (see also [15,28,49] for the case n = 2 and [1,14,29,47,48,61,63] for the case n = 3). However, the stability of these equilibria is not known for general dimension n but only for n = 2 [28], n = 3 [1,29,47,48] and n = 4 [31].…”

“…To complete the characterization of the equilibria, we need to solve the compatibility equation (78). As pointed out above, this has been done in any dimension n in [56] (see also [49] for n = 2 and [1,29,47,48,63] for n = 3). This result is summarized without proof in the following lemma Lemma 4.4 (Final characterization of the equilibria [56]).…”

“…As pointed out above, this has been done in any dimension n in [56] (see also [49] for n = 2 and [1,29,47,48,63] for n = 3). This result is summarized without proof in the following lemma Lemma 4.4 (Final characterization of the equilibria [56]). Let f be an an equilibrium.…”

“…1b). In all cases, the equation ρ n (λ) = ρ has a solution if and only if ρ ≥ ρ * and this solution is unique in the case n = 2 while, in the case n ≥ 3, there are two solutions if ρ ∈ (ρ * , ρ n (0)], and one solution if ρ ∈ {ρ * } ∪ (ρ n (0), ∞) (see [56] for details).…”

From kinetic to fluid models of liquid crystals by the moment method

Body-Attitude Alignment: First Order Phase Transition, Link with Rodlike Polymers Through Quaternions, and Stability

Phase Transitions and Macroscopic Limits in a BGK Model of Body-Attitude Coordination