针对现有再生水处理工艺中无法有效去除顽固型有机物，以及新型纳米矿物催化技术在反应中存在效率低、难回收等问题的现状，提出开发可磁性回收的尖晶石纳米MFe2O4为基础的MFe2O4/二维(BiO)2CO3复合纳米矿物催化材料，探索该复合材料的可控合成方法。通过能级调控提供羟基自由基，利用二维(BiO)2CO3良好的水相分散性增加固液反应接触面积，提高顽固型有机物降解效率。考察水环境因素对该复合纳米矿物材料的催化性能和降解机理的影响，评价其在不同水质中的运行效能，阐明关键水环境因素影响活性物种的机制。解析典型顽固型有机物在MFe2O4/二维(BiO)2CO3体系中降解的中间产物，构建多参数的反应动力学模型，实现体系中目标污染物和副产物的同步预测，结合反应前后水质的生物毒性，阐明体系的脱毒机制。研究结果为再生水中顽固型有机物提供一种深度处理技术，并对该技术的可行性和安全性提供科学数据支撑。

Since the current reclaimed water facility is disable to the removal of refractory organic pollutants, the mineral catalyst technology is developed to solve this problem. However, its nature of low efficiency and difficult seperation restrains the application. In this project, to make a recyclable process, the magnetic spinnel MFe2O4 is chosen as the target mineral catalyst. Furthermore, two-dimension (2D) (BiO)2CO3 is introduced to MFe2O4 to form a MFe2O4/2D (BiO)2CO3 nano composite, which will provide a new reactive oxygen species (ROS) namely hydroxyl radical. The hydroxyl radical is a powerful ROS to mineralize refractory organic pollutants. In addition, the 2D (BiO)2CO3 can be well dispersed in the aqueous solution, which improves the contact between catalyst and pollutants, as well as catalytic performance. As a result, the MFe2O4/2D (BiO)2CO3 nano composite is capable for degrading refractory organic pollutants in reclaimed water. To evaluate the performance in different water quality, the removal efficiency and ROS reaction mechanism are investigated at different environmental parameters, such as temperature, pH, ions and co-exist pollutants. Moreover, the degradation mechanism and reaction pathway of refractory organic pollutants are studied as well as the detoxicity mechanism. This project provides a new strategy for the reclaimed water. It also gives suggestion on the practicability and safety of the MFe2O4/2D (BiO)2CO3 photocatalysis process.