In this thesis, the molecular orientation and dielectric characteristics of high dielectric anisotropy nematic liquid crystal (NLC) cells under ultraviolet (UV) light exposure are investigated by means of dielectric spectroscopy. In experiments, time-varying complex dielectric spectra of NLC cells under UV exposure were measured with fixed UV intensity of 20 mW/cm2 and varied temperatures (T), ranging from 10 to 70 C. The dielectric spectrum in the high-frequency (f > 1 kHz) and low-frequency (f < 1 kHz) are used to discuss the molecular and ionic properties of a NLC cell, respectively. Moreover, pretilted angle and transmission spectra measurements and DiMOS simulations were performed to further confirm the effect of UV exposure on the molecular alignment of the high dielectric anisotropy NLC. In the case of T = 10 C, the real-part dielectric permittivities (ε’) in the high frequency regime firstly get increased and the imaginary-part dielectric spectrum (ε”(f)) red-shifts (i.e., shifting to low frequencies) with raising UV exposure time. In contrast, when the UV exposure time is higher than a critical value (tc), the change of ε’ in the high frequency as a function of the UV exposure time becomes gentle but ε”(f) starts blue-shifting (i.e., shifting to high frequencies). Because the surface alignment of used cells is planar and the NLC exhibit positive dielectric anisotropy the decreased value of ε’ can directly be attributable to the decrease in the tilted angle of NLC molecules as confirmed further by pretilted angle and transmission spectra measurements. Furthermore, by fitting complex dielectric spectra with appreciated formula, the time-varying ionic behavior of the NLC cell under UV exposure are clarified in terms of the dc conductivity and the diffusivity. It is suggested that both the dc conductivity and diffusivity preserve as constants with time at the temperature conditions of T = 10 C and 20 C but they start increasing with raising UV exposure time when the temperature is higher than 20 C. Since the ion-transport gets promoted with increasing temperature in a LC cell, it is implied that ions can readily receive enough energy from the UV light to diffuse within the cell at high temperature. Finally, an individual study concerning the illumination of UV light to the cell before LC injection was preliminarily investigated. As confirmed by transmission spectra, pretilted angle measurement and DiMOS simulation, similar result to the decrease in the tilted angle of LC molecules can be found in this experiment as well. Further experiments are worth investigating separately in the future.