Ciprofloxacin is a fluoroquinolone antibiotic that is widely used in the treatment of serious bacterial infections, and it is often released into surface water through hospital wastewater and wastewater treatment plant effluent. The literature has demonstrated its photodegradation potential in natural surface water, but there is limited information about its photochemical behavior in the sorbed state. Ciprofloxacin interacts strongly with solid matrices (e.g., clay minerals, humic substances, and hematite) with potentially different photolysis mechanisms. Therefore, the objective of this study is to investigate the photochemistry of ciprofloxacin in a solid-phase system compared to a water-phase system. Kaolinite was used as the model matrix in this study, and methods were established for the pretreatment, extraction, purification and analysis of ciprofloxacin in kaolinite at the μg g-1 level. The recovery of the extraction method ranged from 96.6% to 113.4%, and the limit of detection was 10 μg g-1. The interaction between ciprofloxacin and kaolinite surface might affect photochemical property of ciprofloxacin. The molar extinction coefficient of ciprofloxacin in kaolinite was 5.8×106 mole-1 L cm-1 at 330 nm based on the Kubelka-Munk function, which was greater than in the water phase (maximum value of 3×104 mole-1 L cm-1 at 271 nm at pH 7). Moreover, ciprofloxacin is more persistent when it is adsorbed onto kaolinite under irradiation. Photolysis of ciprofloxacin in kaolinite with various depths were conducted and photolysis rate constants (kp) were determined by fitting pseudo-first order in the first hour. kp dramatically decreased from 0.0154 min-1 to 0.0016 min-1 as the layer thickness (Z) increased from 14 μm to 199 μm. kp×Z was constant (0.30 μm×min-1), and kp0 (pseudo-first order constant at the surface of the kaolinite layer, where Z=0 μm) was 0.034 min-1 according to Balmer’s model. The half-life of ciprofloxacin in kaolinite was 20 times longer than in the water phase under simulated sunlight, thus increasing the potential environmental risk. Furthermore, the interaction between ciprofloxacin and kaolinite did not result in other photosensitization reactions, and it reduced the direct photolysis; therefore, similar photodegradation pathways were identified from direct photolysis of water phase. The amounts of byproducts were semi-quantified by the calibration curve of standard ciprofloxacin and cleavage of the piperazine ring is the main degradation pathway of ciprofloxacin in kaolinite (38.6% yield of P2, MW=262); other initial degradation pathways include oxidation of the piperazine ring (P3, MW=290) and cleavage of the cyclopropyl group (norfloxacin and P4, MW=293). Norfloxacin was produced with a 17.6% yield in the water phase and a 0.95% yield in kaolinite. Defluorination caused by the addition of OH- resulted in P5 (MW=329) and was only observed in the water phase, likely due to the absence of water in kaolinite. This study indicated that ciprofloxacin is more environmentally persistent in kaolinite than in water. However, the fate of antibiotics in natural sediments and soils is more complicated since the matrix is highly heterogeneous; our knowledge is far from complete in this field. Future work should focus on additional factors, such as humic substances and metal ions, in the solid phase to investigate the photochemical reaction of ciprofloxacin in sediment and in the water/solid phase.