姓名：程振民

職稱：教授
所屬單位：華東理工大學化工學院
電話：(021)64253529
傳真：(021)64253528
電子郵件：zmcheng@ecust.edu.cn

教育背景：
 2002/06-2003/05，澳大利亞昆士蘭大學化學工程系，訪問學者
 2000/11-2001/02，法國國家科研中心化學工程科學實驗室，訪問學者
 1990/09-1993/07，華東理工大學聯合化學反應工程研究所，博士
 1987/09-1990/07, 華東理工大學化學工程研究所，碩士
 1983/09-1987/07, 華東理工大學化學工程系，學士

工作經曆：
 2002/03-至今，華東理工大學化工學院，聘任博士生導師
 1999/11-至今，華東理工大學化工學院，教授,碩士生導師
 1996/11-1999/10, 華東理工大學化工學院，副教授
 1993/10-1996/10, 華東理工大學化工學院，講師

研究方向：

反應器模拟與内構件設計；多相流模拟計算與基礎理論；界面工程與過程強化；多孔介質模拟; 新型催化反應工程；電化學反應工程；二氧化碳轉化與利用。

榮譽和獎勵：

上海市化學化工學會莊長恭提名獎(2004)

教育部新世紀優秀人才支持計劃(2004)

中國大學出版社圖書獎第二屆優秀教材二等獎(2012)

優秀研究生任課教師一等獎（2017）、優秀研究生教學成果二等獎（2019）

學術兼職：

華東理工大學學報、化學反應工程與工藝、管道技術與設備、Processes、Int. J. Eng. Sys. Model. Simul.雜志編委，全國催化加氫技術指導委員會委員，及多個學術會議和組織的學術委員。

承擔科研項目：

1. 廢棄稭稈制備能源化學品成套技術與裝備，國家重點研發計劃，2020-2022.

2. 非潤濕型氣-液-固三相接觸方式的構建及應用研究，國家自然科學基金，2017-2020.

3. 萘磺化反應旋流閃蒸脫水設備研制，企業委托，2022-2023.

4. 2-萘酚連續反應技術研發及改造項目，企業委托，2021-2022.

5. 加氫反應器氣液旋流混合内構件，企業委托，2021.

6. 超臨界廢水脫鹽結晶過程研究，企業委托，2020-2022.

7. 基于沸騰床平台的相關技術研究，企業委托，2019-2021.

8. 大型煉油基地設計技術升級與提質增效技術開發應用，企業委托，2018-2020.

9. 單套2萬噸/年甲基氯化鋁連續生産工藝及其反應器的研制，企業委托，2018-2020.

10. 沸騰床加氫裝置工程技術開發，企業委托，2018-2019.

代表性論著：

 (一)研究生教材

1) 程振民, 朱開宏, 袁渭康. 高等反應工程. 化學工業出版社, 北京，2021.

2) 朱開宏, 程振民. 高等反應工程教程例題與習題（附MATLAB 算例）. 華東理工大學出版社, 上海, 2012.

3）程振民, 朱開宏, 袁渭康. 高等反應工程教程. 華東理工大學出版社, 上海, 2010.

 (二)近期所發表學術論文

1)  Yan S, Mahyoub SA, Lin J, Zhang C, Hu Q, Zhong J, Cheng ZM*. Controllable growth of branched silver crystals over a rod of the same material as an efficient electrode in CO2 reduction at high current densities. Journal of Catalysis. 2022;405:224-35.

2)  Yan S, Mahyoub SA, Lin J, Zhang C, Hu Q, Chen C, Cheng ZM* Au aerogel for selective CO2 electroreduction to CO: ultrafast preparation with high performance. Nanotechnology. 2022;33(12).

3)  Xu C, Cheng ZM*. Dicationic Imizadolium-Based Tetrafluoroborate Ionic Liquids: Synthesis and Hydrothermal Stability Study. Chemistryselect. 2022;7(32).

4)  Tang Y, Luo G, Zhong J, Chen K, Xu C, Cheng ZM*. Effects of stagnant zone on the effectiveness factor in a trickle bed. Chemical Engineering Science. 2022;248.

5)  Tang Y, Luo G, Cheng ZM*. Packing size effects on the liquid circulation property in an external-loop packed bubble column. AIChE Journal. 2022.

6)  Song Y, Li Z, Zhu Q, Huang Z, Cheng ZM*. Precipitation Behavior of Salts in Supercritical Water: Experiments and Molecular Dynamics Simulations. Processes. 2022;10(2).

7)  Mahyoub SA, Qaraah FA, Yan S, Hezam A, Zhong J, Cheng ZM*. Rational design of low loading Pd-alloyed Ag nanocorals for high current density CO2-to-CO electroreduction at elevated pressure. Materials Today Energy. 2022;24.

8)   Mahyoub SA, Qaraah FA, Yan S, Hezam A, Chen C, Zhong J, Cheng ZM*. 3D Cu/In nanocones by morphological and interface engineering design in achieving a high current density for electroreduction of CO2 to syngas under elevated pressure. Journal of CO2 Utilization. 2022;61.

9)   Liu J, Shi J, Zhang B, Cheng ZM*. Novel Magnetically-Recoverable Solid Acid Catalysts with a Hydrophobic Layer in Protecting the Active Sites from Water Poisoning. Processes. 2022;10(9).

10)Lin J, Yan S, Zhang C, Hu Q, Cheng ZM*. Hydrophobic Electrode Design for CO2 Electroreduction in a Microchannel Reactor. Acs Applied Materials & Interfaces. 2022;14(6):8623-32.

11) Lin J, Yan S, Zhang C, Hu Q, Cheng ZM*. Electroreduction of CO2 toward High Current Density. Processes. 2022;10(5).

12) Cheng ZM*, Luo G, Tang Y, Ling D, Chen Z, Liu P. External Wetting Efficiency in a Three-Phase Fixed Bed Loaded with Porous and Non-Porous Packings. Processes. 2022;10(1).

13) Chen K, Cao Y, Zhu H, Ge H, Yang T, Zhou Z, Cheng ZM*. Experimental Determination on the Deactivation Kinetics of Residue Hydroprocessing in a Two-Stage Fixed Bed Loaded with HDM and HDS Catalysts. Processes. 2022;10(9).

14) Zhang C, Yan S, Lin J, Hu Q, Zhong J, Zhang B, Cheng ZM*. Electrochemical Reduction of CO2 to CO on Hydrophobic Zn Foam Rod in a Microchannel Electrochemical Reactor. Processes. 2021;9(9).

15) Yan S, Mahyoub SA, Zhong J, Chen C, Zhang F, Cheng ZM*. Ultrathin and dense Ag nanosheets synthesis under suppressed face (111) growth and surface diffusion. Journal of Power Sources. 2021;488

16) Yan S, Chen C, Zhang F, Mahyoub SA, Cheng ZM*. High-density Ag nanosheets for selective electrochemical CO2 reduction to CO. Nanotechnology. 2021;32(16).

17) Xu C, Cheng ZM*. Thermal Stability of Ionic Liquids: Current Status and Prospects for Future Development. Processes. 2021;9(2).

18) Tang Y, Luo G, Zhou Z, Li J, Gao G, Li L, Cheng ZM*. An analysis on catalyst wettability design in strong exothermic reactions. Chemical Engineering Science. 2021;246.

19) Shi J, Zhang L, Cheng ZM*. Design of Water-Tolerant Solid Acids: A Trade-Off Between Hydrophobicity and Acid Strength and their Catalytic Performance in Esterification. Catalysis Surveys from Asia. 2021;25(3):279-300.

20) Zhang F, Jin Z, Chen C, Tang Y, Mahyoub S, Yan S, Cheng ZM*. Electrochemical Conversion of CO2 to CO into a Microchannel Reactor System in the Case of Aqueous Electrolyte. Industrial & Engineering Chemistry Research. 2020;59(13):5664-74.

21) Zhang F, Chen C, Yan S, Zhong J, Zhang B, Cheng ZM*. Cu@Bi nanocone induced efficient reduction of CO2 to formate with high current density. Applied Catalysis a-General. 2020;598.

22) Zhang F, Chen C, Tang Y, Cheng ZM*. CO2 reduction in a microchannel electrochemical reactor with gas-liquid segmented flow. Chemical Engineering Journal. 2020;392.

23) Tang Y, Chen M, Cheng ZM*, Yang T, Chen B, Ge H, Fang X*. Effectiveness factors for a partially wetted catalyst based on the rivulet flow model. Chemical Engineering Science. 2020;215.

24) Mahyoub SA, Qaraah FA, Chen C, Zhang F, Yan S, Cheng ZM*. An overview on the recent developments of Ag-based electrodes in the electrochemical reduction of CO2 to CO. Sustainable Energy & Fuels. 2020;4(1):50-67.