In this thesis, we consider several colloids of the 4-n-octyl-4’-cyanobiphenyl liquid crystal (LC) 8CB doped with graphene nanoplatelets (GNPs) and investigate the phase and ionic behaviors by means of temperature-dependent dielectric spectroscopy and observations of microscopic textures. The phase sequence and transition temperatures between two adjacent phases of both pure and GNP-doped 8CB are clarified according to the data of the first derivative of the real-part dielectric permittivity with respect to the temperature. Moreover, based on our previous studies of the ionic effect in LC cells, the dielectric spectra in the low-frequency regime (f  ≤  1 kHz) characterized by space-charge polarization, allow one to investigate the impurity-ion properties of GNP-doped LC cells in comparison with their neat counterpart. Experimental results indicate that GNPs are responsible for modifying the phase transition temperatures of the LC 8CB. Especially for the transition temperature between the crystalline and the SmA phases in the heating cooling process, it is found that the value is approximately increased by 5 °C as the content of GNPs is increased from 0.3 to 0.7 wt%. Noticeably, the pure 8CB in the crystal phase exhibits regular a single-domain texture whereas it becomes random poly-domains in the GNP-doped 8CB cells. It is suggested that the interaction between the LC molecules and GNPs leads to the gradient change in molecular ordering in the bulk of the cell; thus, the GNPs suspended in the 8CB cells can be regarded as nuclei during the crystallization. In regard to the ionic behavior in the cells, our results based on dielectric analysis show that the ionic concentrations in GNP-doped 8CB cells are lower than that in the pure counterpart. This suggests that a minute amount of GNPs as an ion-suppressor can effectively trap impurity ions in 8CB cells.