This thesis focuses on phase behaviors of blue-phase-liquid-crystal (BPLC) materials. The phase-transition temperatures and ionic behaviors of BPLC materials are investigated by means of temperature-dependent dielectric spectroscopy. By introducing BPLCs into planar-aligned cells, the phase sequence and transition temperatures between two adjacent mesophases of three distinct BPLC mixtures (R5011-doped HDE, R5011-doped E7, and S811-doped E7) are clarified according to the data of the first and the second derivatives of the real-part dielectric permittivity at a specific frequency with respect to the temperature. Furthermore, based on our previous studies for the ionic effect in BPLC (HDE/R5011) cells, the dielectric spectra in the low-frequency regime (f  ≤  5 kHz) characterized by space-charge polarization allow one to investigate the impurity-ion properties of BPLC cells in comparison with those of their neat counterparts. Experimental results indicate that the phase sequence of a BPLC can clearly be defined through the temperature-dependent dielectric spectroscopy on the cooling process. The percent error of measurement of this dielectric method is very small. The maximum percent errors of the first-order and the second-order phase transition are 0.20% and 0.46%, respectively. Compared to other phase identification methods, the area of a BPLC sample and the measurement-range restriction of instrument cannot affect the data of the temperature-dependent dielectric spectroscopy. In regard to the ionic behavior in the BPLC cells, experimental results show that the ion- concentration value of BPLC cells changes owing to different phases. Moreover, the environmental temperature of BPLC cells can affect the ionic diffusivity in cells rather than phase transition.