Volatile organic compounds (VOCs), one of indoor air pollutants, are related to aggravation of indoor air quality (IAQ), such as health effect to human and Sick Building Syndrome (SBS). This study selected trichloroethylene (TCE) as model pollutant with respect to the common substance in indoor environment, such as lubricants or correction fluids. The advantages of Photocatalytic Oxidation (PCO) listed as followed: available to several compounds, operation in room temperature, and to be mineralized to H2O or CO2. It has becoming tendency for this process applied to indoor air clean technology. The intermediates, which generated from the PCO process, may raise the concerns of photocatalyst deactivation. Previous studies indicated that the ozone addition has the enhancement effect on this process, however, the ozone concentration has a recommended value of indoor environment because of the negative effect to human health. Therefore, one of the objectives of this study is to investigate of ozone addition to PCO process, the intermediates control ability and ozone removal efficiency. The experiments were conducted in a photoreactor, with a rectangular quartz plate (45 cm in legth and 2.5 cm in width). The UV light source was controlled at 254 nm and 15 W. Also, Degussa P25 TiO2 was chosen as the catalyst in this study. The influential factors including TCE concentration, relative humidity, gas flow rate and ozone concentration were evaluated and performed twice for reproductive assurances. The effect of gas-phase mass transfer was negligible when gas flow rate exceeded 1,600 ml/min. And the PCO kinetics fitted Langmuir-Hinshelwood model well for bimolecular competitive adsorption type. The TCE conversion and CO2 evolution decreased with increasing TCE concentrations. However, the TCE oxidation rate showed the opposite effect. The residual intermediates increased with increasing TCE concentrations. The PCO rate constants ranged from 10.7 to 11.3 μ-mole m-2s-1, and linear-correlated to the VOCs-hydroxyl radical rate constants (kOH•). The Langmuir adsorption constants of VOCs and water ranged from 0.61 to 0.70 ppm-1 and 8.33×10-3 to 1.67×10-2 ppm-1, respectively. A linear positive relationship was found between the reciprocal of Langmuir adsorption constants and Henry’s Law constants of TCE. However, the reciprocal of Langmuir adsorption constants of water showed a negative relationship with Henry’s Law constants of TCE. This might be due to the intermediates, converted form TCE, reacted with water, and caused the dissipation of water. Relative humidity has a enhancement effect to hydroxyl radicals and retardation effect because of competitive adsorption. Results indicated that the increase of water vapor, the intermediates could decrease from 60% to around 40%. Also, the longer the retention time, the higher the CO2 yield rate. The reason was the contact ability between intermediates and water. The ozone addition to the process of UV/TiO2 exhibited slightly enhancement. When the addition from 100 to 500 ppb of ozone, namely the ratio of O3/TCE is 0.1, the intermediates could slightly controlled around 5%. However, the ratio higher than 0.1, it started to retard. When the addition was 1000 ppb, it still remained about 35% (UV/TiO2/O3) and 40% (UV/O3) of residual intermediates, respectively. The ozone concentration showed retardation effects to UV/O3 and UV/TiO2/O3 processes. The oxidation rate decreased when the addition concentration increased. That was due to the released of Cl•and competed with OH•. These two radicals competed for TCE and water molecules. Owing to the higher reaction rate of Cl•with ozone than that of OH•with ozone by two magnitudes (128 times), ozone has devastated. This results also corresponded to the negative value of enhancement indices of ozone. Therefore, it seems that the enhancement effect was not found at the ratio of O3/TCE (0.1). In summary, under whether processes (UV/TiO2, UV/TiO2/O3 or UV/O3), the CO and CO2 yield rate increased (only under UV/O3 process gained no CO). It showed that TCE converted to residual intermediates and accompanied the reaction of hydrolysis. Therefore, the end products would be CO and CO2. However, the CO yield of UV/O3 was too low to be detected by the Q-trak.