Abstract:The removal efficiencies and degradation kinetics of the target H-acid from multi-component aqueous solutions in suspended photocatalytic nanofiltration membrane reactor were performed, the concentrations of co-existing Tobias acid and Chromotropic acid were set to 5, 10, 20, 25and 40mg/L respectively, while the target H-acid was set to be 100mg/L. The experimental results indicated that, in the single-component reaction system, the photocatalytic degradation kinetics of H-acid obeyed the combined reaction kinetics model of L-H zero-order (about 0~12min) and L-H first-order (about 12~20min) within Ct/C0 3 0.7; while it imperatively obeyed the L-H first-order reaction kinetics model (0~20min) in the multi-component system within the same range. The drastic changes in H-acid degradation kinetics were mainly attributed to its substantial concentration differences both in the photocatalytic membrane reactor and on the photocatalyst surface between the single-component and multi-component conditions.