Emerging pollutants are defined as chemical pollutants that “have not yet been identified or confirmed”, “are unregulated” and “pose a risk to human health and the environment” (Mandaric et al., 2015). This type of pollutant also cannot be effectively removed by the treatment units of existing sewage treatment plants and water purification plants. In Taiwan, people are particularly concerned about this issue because Taiwan passed U.S. beef, containing ractopamine, imports in early 2020. Moreover, due to the outbreak of the epidemic, many scholars have devoted themselves to developing medicines for covid-19. And quinine is one of the medicines for covid-19. Unfortunately, both of these compounds are emerging contaminants. Although the concentrations of these pollutants entering the environmental water body are very low, after a long period of exposure will have a bad impact on the ecosystem. Therefore, this study will implement an advanced oxidation procedure To degrade the target compound, the Fenton degradation process and the advanced oxidation process of persulfate were used as treatment methods and the treatment efficiency of the two methods in treating the target pollutants was compared at the same time, and the catalyst was changed in the experiment at the same time, and the homogeneous catalysis (ferrous sulfate) was compared. ) and heterogeneous catalysis (iron tetroxide) on the removal ratio of target pollutants; in addition, graphene and humic acid will be added as chelating agents in this experiment to compare the effect of adding chelating agents on the overall reaction mechanism; The study will adjust the operating environment to a neutral environment and simulate the operational feasibility of the Fenton method and the persulfate oxidation method in a neutral-to-acidic environment. In addition, this study will use a mass spectrometer to define the oxidation program experiment Intermediate products in the process. And input the results into the calculation software to calculate the ecological structure-activity relationship to confirm that the degradation reaction can solve the biological toxicity of pollutants in the environment. The results of this study showed that in the comparison of homogeneous catalysis and heterogeneous catalysis, it can be found that the homogeneous catalysis effect of ferrous ions as the catalyst is better than that of ferric ferrous oxide. Adding a chelating agent can also increase the overall reaction result, especially when adding graphene as a chelating agent, the overall reaction rate and degradation efficiency are significantly improved. In an acidic environment, ferrous ions are more active. While in a neutral environment, ferrous ions are mostly converted into less active iron ions. Therefore, the overall degradation effect is not as good as the acidic condition. However, in the ferric ferrous oxide catalysis experiment. Changing the pH value only caused little difference, showing that in the environment with a neutral pH value or a large fluctuation, the ferric ferrous oxide as a high-grade catalyst of the advanced oxidation procedure has higher feasibility. Finally, the degradation pathways and mass spectrometry results of the two emerging pollutants are input into the software of EPI Suite to obtain the biological toxicity, and it can be found that most of the pollutants are removed. Therefore, it can be speculated that the Fenton process and the sulfate radical-based advanced oxidation process are feasible methods in the degradation process of pollutants.