Pharmaceuticals and personal care products (PPCPs) are commonly detected in the aqueous environment at ng/L to ng/g concentration levels since pharmaceuticals in wastewaters cannot be effectively removed through biological wastewater treatment. In recent years, UV based advanced oxidation procedures (UV-AOPs) was applied to improve degradation of PPCPs; however, energy consumption and power costs are important issues. Therefore, this study is aimed to design a sunlight concentrator treatment system to replace UV lamps for further degradation of pharmaceuticals. To increase efficiency of the sunlight concentrator treatment system, the sunlight tracker was used jointly in this study, and the surface of concentrator was also modified to enhance UV reflection rates. Two common antibiotics, ciprofloxacin and sulfamethoxazole, were chosen as target compounds in this study. The results show that degradation efficiencies of ciprofloxacin and sulfamethoxazole respectively increased in water-based substrate as high as 40%-48% and 4.2%-13.6% in the enhanced system at noon on the summer of Taiwan compared with direct sunlight photolysis system. In order to further improve the degradation efficiency of the system, free chlorine (HOCl, OCl−, FC) and persulfate (S2O82- , PS) were added. For sulfamethoxazole, 1 mg/L of FC addition could lead to 33% increase of degradation efficiency, and 50 mg/L of PS addition could improve further degradation as high as 61%. The enhanced system can not only collect sunlight but also raise the temperature in the reactor. Because PS can be activated by light and heat, the enhanced system was suitable to activate PS to generate sulfate radical (·SO4−) and degrade sulfamethoxazole. The result shows that PS addition leads to synergic effect on sulfamethoxazole degradation in the system. Therefore, this developed sunlight concentrator treatment system will have potential to be utilized in the wastewater treatment process.