This thesis investigates effect of the ultraviolet (UV)-light exposure on the dielectric properties of nematic liquid crystals (NLCs) with different degree of degradation. Here, two bottles of NLC E44 purchased in 2011 and 2014 are regarded as degraded and fresh LCs, respectively. The content of this thesis is divided into three parts. The first part is concerned with the effect of UV intensity on time-varying dielectric features of both fresh and degraded LCs at fixed temperature. In the second part, sealed and unsealed LC cells were fabricated and their time varying dielectric spectra were measured. After keeping cells undisturbed for 30 days, the dielectric and ionic properties of these cells varying with time under UV exposure are further discussed. By fixing the fresh LC cell at 70 C where the complex dielectric spectrum is similar to that of degrade LC at room temperature, the final part is to discuss the dielectric properties of the fresh LC under UV exposure at a given temperature and compare them to those of the degraded counterpart at room temperature. Under the condition of UV exposure, the dielectric spectra attributable to the space-charge polarization in the middle frequency regime of both the fresh and degraded LCs shift to high frequencies with time due to the dissociation of LC material itself and/or ion injection from the alignment layer. Because the ion density of the fresh LC is lower than that of the degraded counterpart, the saturated time in which the dielectric spectra stops shifting of the fresh LC is shorter than that of the degraded LC. Noticeably, in the low frequency regime where the complex dielectric constant is attributable to accumulation of ions near the substrate and thus the electrode polarization, the imaginary-part dielectric permittivity gets increased with increasing UV exposure time and then becomes saturated at a critical time. For cells sealed with AB glues, the shift of dielectric spectra to high frequency with time of both the fresh and degraded LCs are greater than those of the unsealed counterparts, indicating the degradation primarily dominated by the glues. Based on results of dielectric spectra, the ionic properties of the LC cells under UV exposure are further discussed in terms of the dc conductivity and ion density. It is found that the ion density of both the fresh and degraded LC cells get promoted with increasing UV exposure time.