高纯化学品高效精制；高端医药绿色精制；高盐废水及固废资源化；工业结晶过程优化及设备开发；

本科生限选课《化工计算与机器学习基础》；

本科留学生全英文课《Introduction to Chemical Engineering Design》；

研究生选修课《工程最优化方法》；

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2019年度天津市科学技术进步特等奖；

2021年度天津市科学技术进步一等奖；

2022天津市专利优秀奖；

国家重点研发计划课题“高盐废水蒸发结晶脱盐及回用技术与示范”；

国家自然科学基金项目“含锂水盐体系介稳相平衡的PAT在线快速检测过程研究”；

国家自然科学基金项目“生物分子高通量检测用量子点激光微球的制备及多色激光的实现”；

产学研横向项目“对二甲苯熔融结晶分离技术研究”，“高纯PVP单体NVP制备技术开发及产业化”，“注射用大颗粒碳酸氢钠制备技术及中试设备开发”，“年产3000吨大颗粒结晶碳酸氢钠项目设计与研究”，“高纯碳酸亚乙烯酯熔融结晶过程研究与开发”，“NAU反应结晶新技术及连续结晶设备研发”，“苯酚-

图书：主稿《化学工程手册》（第三版）第一篇《化工基础数据》；参编：《化工基础实验数字课程》；论文：1. Ye, Y., et al., Flexible Optical Waveguides in Heterocyclic Schiff Base Self-Assembled Hydrogen-Bonded Solvates. Crystal Growth & Design, 2023: p. 9.

2. Sun, Y., et al., Tuning Solid-State Emission of 9-Anthraldehyde through Cocrystal Engineering. Crystals, 2023. 13(4): p. 9.

3. Sun, Y., et al., Mechano-/seeding-triggered crystal-to-crystal phase transition in luminescent switching cocrystals. Dyes and Pigments, 2023. 215: p. 8.

4. Qi, L.G., et al., Effect of functional group position in co-formers and solvent on cocrystal polymorphism/stoichiomorphism: a case study. Journal of Molecular Liquids, 2023. 388.

5. Hu, X.C., et al., An Attempt to Design Thermosalient Crystals by Co-Crystallization: The Twisted Angle between Aromatic Rings. Crystals, 2023. 13(4): p. 13.

6. Hu, X.C., et al., Enhancing the dissolution and bacteriostatic activity of trimethoprim through salt formation. Crystengcomm, 2023. 25(23): p. 3445-3459.

7. Bai, Y.H., et al., Modeling and Operating Time Optimization of Layer Melt Crystallization and Sweating Processes. Processes, 2023. 11(4): p. 11.

8. Bai, Y.H., et al., Purity-Targeted Prediction of the Cooling Profile in Layer Melt Crystallization via Thermal Approximation. Industrial & Engineering Chemistry Research, 2023. 62(18): p. 7152-7159.

9. Zhang, Z., et al., Optimizing the Mechanical Performance and Microstructure of Alkali-Activated Soda Residue-Slag Composite Cementing Materials by Various Curing Methods. Sustainability, 2022. 14(20): p. 14.

10. Zhang, Z., et al., Mechanical Properties and Microstructure of Alkali-Activated Soda Residue-Blast Furnace Slag Composite Binder. Sustainability, 2022. 14(18).

11. Ye, Y., H. Hao, and C. Xie, Photomechanical crystalline materials: new developments, property tuning and applications. Crystengcomm, 2022. 24(17): p. 3136-3149.

12. XuanYuan, S., et al., Quantitative analysis of solid and liquid contents in reactive crystallization by in-situ Raman with support vector regression. Journal of Crystal Growth, 2022. 587.

13. Song, T., et al., Solubility Measurement and Data Correlation of Pyrimethamine in 13 Pure Solvents at Temperatures from 278.15 to 318.15 K. Journal of Chemical and Engineering Data, 2022. 67(1): p. 28-36.

14. Qi, L.G., et al., The habit evolution of 6-amino-1,3-dimethyl-5-nitrosouracil hydrate: Effect of acid and polymer additives. Journal of Crystal Growth, 2022. 600: p. 8.

15. Lan, J., et al., Simultaneous control of polymorphism and morphology via gelatin induction for concomitant systems: case study of sulfathiazole. Crystengcomm, 2022. 24(25): p. 4584-4592.

16. Bai, Y.H., et al., Prediction of the Layer Growth Rate in Static Melt Crystallization. Industrial & Engineering Chemistry Research, 2022. 61(50): p. 18530-18536.

17. Bai, Y., et al., Facile Model for Predicting Sweat Mass and Concentration in Layer Melt Crystallization. Industrial & Engineering Chemistry Research, 2022. 61(10): p. 3704-3712.

18. Yan, L., et al., Determination and Correlation of Solubility of Quizalofop-p-ethyl in Seven Pure Solvents and Three Binary Solvents. Journal of Chemical and Engineering Data, 2021. 66(5): p. 2244-2255.

19. Xiao, Y., et al., Cocrystals of Propylthiouracil and Nutraceuticals toward Sustained-Release: Design, Structure Analysis, and Solid-State Characterization. Crystal Growth & Design, 2021. 21(2): p. 1202-1217.

20. Xiao, Y., et al., Growth mechanism of the spherulitic propylthiouracil-kaempferol cocrystal: new perspectives into surface nucleation. Crystengcomm, 2021. 23(12): p. 2367-2375.