1. 无序生物质碳的宏观构筑及污染控制应用

基于生物质的资源化与高值化转化，利用水热过程对生物质组分进行定向调控，实现生物质碳的无序有序转化及宏观构筑，瞄准碳材料在污染控制应用过程中的难点问题，推进生物质碳材料的先进环境应用。

1. Hydrothermal Treatment of Biomass Feedstocks for Sustainable Production of Chemicals, Fuels and Materials: Progress and Perspectives. Chemical Reviews, 2023, 123, 7193-7294. link

2. Kraft Lignin-derived Multi-porous Carbon toward Sustainable Electro-Fenton Treatment of Emerging Contaminants. Resources, Conservation and Recycling, 2024，203, 107413. link

3. Synthesis of biowaste-derived carbon foam for CO2 capture. Resources, Conservation and Recycling, 2022，185, 106453. link

2. 有序纳米碳材料的环境功能调控

基于碳纳米材料的物化特性，面向环境应用，利用水热等热转化过程调控碳纳米材料的吸附、磁分离、氧化及高级氧化等环境功能。

1. NH2-MCM-41 supported on nitrogen-doped graphene as bifunctional composites for removing phenol compounds: Synergistic effect between catalytic degradation and adsorption. Carbon, 2019，147, 312-322. link

2. Sustainable fabrication of graphene oxide/manganese oxide composites for removing phenolic compounds by adsorption-oxidation process. Journal of Cleaner Production, 2019，215, 165-174. link

3. Iron-catalyzed synthesis of biowaste-derived magnetic carbonaceous materials for environmental remediation applications. Separation and Purification Technology, 2022，295, 121321. link

3. 难降解新污染物的高效降解及转化机制

基于开发的先进环境碳材料，通过耦合光、电、热等技术，实现难降解新污染物的高效降解，同时利用先进表征手段、量子化学计算、超高分辨质谱等，开发非靶向分析方法，解析难降解新污染物在处理过程中的转化机制。

1. Prediction of reaction mechanism for OH radical-mediated phenol oxidation using quantum chemical calculation. Chemosphere, 2022, 291. link
2. Defect Engineering Boosted Peroxydisulfate Activation of Dual-Vacancy Cu-Fe Spinel Oxides for Soil Organics Decontamination. ACS ES&T Engineering Under Revision.
3. Elucidating Adsorption Mechanisms and Characteristics of Emerging Aromatic Organic Contaminants to Graphene Material by Quantum Chemical Calculation Integrated with Interpretable Machine Learning. ACS ES&T Water Under Revision.

4. 先进环境碳材料的器件化及高值化应用

面向科技成果转化，开发基于先进环境碳材料的器件及污染处理体系，拓展在生态领域的高值化应用场景。

1. Swiss-roll electrodes for efficient degradation of carbofuran by electrochemical advanced oxidation processes. Journal of Environmental Chemical Engineering, 2022，10. link

More achievements on the progress!