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Beilstein J. Nanotechnol. 2018, 9, 164–174, doi:10.3762/bjnano.9.19
Figure 1: Schematic representation of the bilayer interdigitated SmA phase of the ILC based on bisimidazolium...
Scheme 1: Synthesis of bisimidazolium salt with dodecyl sulfate anion: (i) Br(CH2)10Br, NaH; (ii) C8H17Br, ac...
Figure 2: POM pictures of [bisC8ImC10][C12H25OSO3]2 on cooling from the isotropic state: at 318 K (a) and at ...
Figure 3: DSC traces for [bisC8ImC10][C12H25OSO3]2: (a) first and (b) second heating–cooling cycle recorded i...
Figure 4: Powder XRD pattern of [bisC8ImC10][C12H25OSO3]2 recorded at 298 K, after cooling from the isotropic...
Figure 5: Permittivity as a function of the temperature (logarithmic scale) for pure ILC (green solid squares...
Figure 6: Dielectric loss as a function of the temperature (logarithmic scale) for pure ILC (green solid squa...
Figure 7: Relaxation time as function of the inverse temperature (logarithm scale) for pure ILC (green solid ...
Figure 8: Permittivity and dielectric loss as functions of the frequency (logarithmic scale) for the pure ILC...
Figure 9: Permittivity and dielectric loss as functions of the frequency (logarithmic scale) at different con...
Figure 10: Real part of the conductivity versus temperature for pure ILC and ILC doped with CNTs, at 10 kHz.
Figure 11: Real part of the conductivity as a function of the frequency (logarithmic scale) for the pure ILC, ...
Figure 12: Conductivity as a function of the CNT concentration at three constant temperatures.
Beilstein J. Nanotechnol. 2018, 9, 155–163, doi:10.3762/bjnano.9.18
Figure 1: Schematic representation of morphology and working principle of the electrospun cellulose network w...
Figure 2: SEM image of deposited electrospun CA fibers.
Figure 3: Polarizing optical microscopy images of the electrospun CA a) without LC and (b) filled with E7.
Figure 4: Dielectric constant and dielectric loss (logarithmic scale) as functions of the temperature for (a)...
Figure 5: Dielectric constant and dielectric loss (logarithmic scale) as functions of the frequency for (a) t...
Figure 6: Relaxation time as a function of the inverse of temperature for the CA/E7 sample.
Figure 7: Active and reactive part of the impedance as functions of the frequency, for (a) the CA cell and fo...
Figure 8: Normalized reactive part of the impedance as a function of the frequency for (a) the CA cell and fo...
Figure 9: Cole–Cole diagrams for (a) the CA cell at 303 K (black solid squares), 313 K (red solid circles), a...
Figure 10: Equivalent three-element model circuit, formed by a serial resistance, Rs, a parallel resistance, Rp...
Figure 11: Optical transmission of the sample CA/E7 as a function of the applied ac electric field.
Figure 12: Schematic representation of electrospinning cellulose fibers from solution.
Figure 13: Experimental set-up for the optical transmission measurement.