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Beilstein J. Nanotechnol. 2019, 10, 1464–1474, doi:10.3762/bjnano.10.145
Figure 1: An NLC layer with CNTs in a magnetic field.
Figure 2: Diagram of orientation phases of the NLC–CNT mixture for γ = 0.2. The horizontal dotted line corres...
Figure 3: Dependencies of (a) the angle φm, (b) the angle ψm, and (c) the reduced CNT volume fraction gm in t...
Figure 4: Spatial distributions of the orientation angle φ(ζ) of the NLC director n for different values of t...
Figure 5: Spatial distributions of the orientation angle ψ(ζ) of the CNT director m for different values of t...
Figure 6: Spatial distributions of the reduced CNT volume fraction g for different values of the magnetic fie...
Figure 7: Dependence of the optical phase lag of the suspension on the applied magnetic field h for γ = 0.2 a...
Beilstein J. Nanotechnol. 2017, 8, 2807–2817, doi:10.3762/bjnano.8.280
Figure 1: The planar layer of LC doped with CNTs in an external magnetic field, choice of the coordinate syst...
Figure 2: The structure of the orientational phases: (a) planar phase, (b) angular phase and (c) homeotropic ...
Figure 3: Diagram of the orientational state of the suspension for (a) γ = 0.1 [σm1 = 0.285, hm1 = 2.738] and...
Figure 4: The tricritical segregation parameter for the Fréedericksz transition as a function of the couplin...
Figure 5: Dependence of the tricritical segregation parameters (a) and (b) on the coupling energy of CNTs w...