杜乐教授 博士生导师、硕士生导师、专业硕士导师
办公地址
北京市朝阳区北三环东路15号北京化工大学无机楼309
电子邮箱
dule@mail.buct.edu.cn
联系电话
010-56492241
招生专业及研究方向
招生专业:
化学工程、化学工程与技术、化学工程与工艺、材料与化工
研究方向:
主要从事微化工技术可控制备精细化学品的研究,包括多相微流控技术的基础理论研究和平台实际应用研究,以及基于微流控技术制备功能微/纳米材料、功能器件和药物中间体
个人经历
2005-2009 清华大学 化学工程与工业生物工程 学士
2008 日本东京大学 机械工程 交换生
2009-2014 清华大学 化学工程与技术 博士
2014-2017 北京化工大学 化工学院 见习副教授
2018-2023 北京化工大学化工学院副教授
2024至今北京化工大学化工学院教授
科研项目
近年来作为项目负责人主持的项目如下:
1.气柱分隔微流体强化浆态合成过程及其流动相似放大方法的研究(国家自然科学基金面上项目,22278015);
2.气液分隔微流体中的光子吸收行为及其对光化学合成影响机制的研究(国家自然科学基金面上项目,21978008);
3. 微尺度液滴可控聚并强化无机纳米颗粒原位分散过程的研究(国家自然科学基金青年基金项目,21506004);
4.XJZ20221100460402,JW科技委;
5.二氯甲烷废气吸附回收(技术转让项目,Z2021-04);
6.一种高浓高盐废水零排放的连续处理方法及装置的专利转让(专利转让项目,Z20230017);
7. 用于光化学合成甾体类药物中间体的LED光源技术开发(横向项目,H20230576);
8. 烟气预处理反应器工艺技术开发(横向项目,H2022171);
9.间苯二甲胺合成新工艺研究(横向项目,H2020133);
10.地屈孕酮光化学反应工艺研究(横向项目,H2017229);
11.维生素D3光化学反应工艺研究(横向项目,H2019153);
12.无机纳米颗粒分散体的可控制备及其在复合薄膜检测器件中的应用(化学工程联合国家重点实验室开放课题,SKL-ChE-16A01);
13.用于颗粒高效分级的微滤膜系统开发及其过程研究(北京化工大学青年后备人才启动基金,buctrc201617)。
学术成就
[1] Ping Liu, Jiawei Zhang, Kefeng Liu, Xuesheng Hu, Fei Gao, Le Du*, Jiqin Zhu*.Aerobic oxidation of 2-tert-butyl phenol within gas–liquid segmented flow: Mass transfer characteristics and scale-up. AIChE Journal, 2023,69, DOI: 10.1002/aic.18057.
[2] Ping Liu, Haodu Li, Yue Tian, Zhangyi Gao, Le Du*, Jiqin Zhu*.Heat-induced fast hydrolysis to produce rutile TiO2 nanoparticles in a capillary microreactor. Chemical Engineering Science, 2023, 281, 119155.
[3] Shudan Chi, Yi Ye, Xinglei Zhao, Junteng Liu*, Junsu Jin, Le Du*, Jianguo Mi. Porous molecular sieve polymer composite with high CO2 adsorption efficiency and hydrophobicity. Separation and Purification Technology, 2023, 307, 122738.
[4] Zhangyi Gao, Yue Tian, Ping Liu, Linjing Jiang, Lili Gao, Le Du*, Jiqin Zhu. Scale-up of synthesizing 3,3-dimethyl-2-butyl ketone (pinacolone) from 2‑methyl-2-butene (β-isoamylene) and its kinetic study. Industrial & Engineering Chemistry Research, 2023, 62, 9453-9462.
[5] Mengchen Li, Zhiyu Zhu, Junteng Liu*, Junsu Jin, Le Du*, Jianguo Mi. Grafting Poly(ethyleneimine) on Macroporous Core–Sheath Copolymer Beads with a Robust Framework for Stable CO2 Capture under Low-Temperature Regeneration. Industrial & Engineering Chemistry Research, 2023, 62, 385-394.
[6] Ping Liu, Lechao Wang, Le Du*, Jiqin Zhu*.Heterogeneous catalytic ozonation of organic wastewater by using bimetallic catalysts supported on honeycomb-structured activated carbon. The Canadian Journal of Chemical Engineering, 2023,DOI: 10.1002/cjce.25099.
[7] Haodu Li, Jie Zhang, Lin Dai, Le Du*, Jiqin Zhu*. Process intensification for the synthesis and purification of battery-grade Li2CO3 with microfluidics. Particuology, 2023, DOI: 10.1016/j.partic.2023.12.001.
[8] Zhangyi Gao, Linjing Jiang, Jiawei Zhang, Jiqin Zhu, Le Du*, Yujun Wang*. Kinetics and Mechanism of Catalytic Oxidation Desulfurization of Gasoline Liquefied Petroleum Gas in MeroxTM Process with Microfluidics. Chemical Engineering & Technology, 2022, 45, 2186-2194.
[9] Yuheng Lu, Xiao Sheng, Jie Zhang, Yujun Wang, Le Du*, Jiqin Zhu*. Cumene autooxidation to cumene hydroperoxide based on a gas-liquid microdispersion strategy. Chemical Engineering & Processing: Process Intensification, 2022, 174, 108861.
[10]Hao Wu, Pu Wang, Le Du*, Junsu Jin, Jianguo Mi*, Jimmy Yun. Design of High-Humidity-Proof Hierarchical Porous P‑ZIF-67(Co)Polymer Composite Materials by Surface Modification for Highly Efficient Volatile Organic Compound Adsorption. Industrial & Engineering Chemistry Research, 2022, 61, 3591-3600.
[11]Ping Liu, Haowei Ge, Yuheng Lu, Yujun Wang, Le Du*, Jiqin Zhu*.Continuous synthesis of 2-tert-butyl phenol oxidation in gas-liquid segmented flow and its kinetic investigation. Chemical Engineering Science, 2022, 248, 117166.
[12]Hanrong Li, Feiyan Han, Linjing Jiang, Tongqian Yang, Le Du*, Jiqin Zhu*. Continuous Synthesis of N‑Cyclohexyl-2-benzothiazole Sulfenamide with Microfluidics and Its Kinetic Study. Industrial & Engineering Chemistry Research, 2021, 60, 14134-14142.
[13]Wenhao Niu, Yuanzhi Zheng, Ying Li, Le Du*, Wei Liu*. Photochemical microfluidic synthesis of vitamin D3 by improved light sources with photoluminescent substrates. Chinese Journal of Chemical Engineering, 2021, 29, 204-211.
[14]Bo Xue, Le Du*, Junsu Jin, Hong Meng*, Jianguo Mi. In situ growth of MIL-88A into polyacrylate and its application in highly efficient photocatalytic degradation of organic pollutants in water. Applied Surface Science, 2021, 564, 150404.
[15]Xiao Sheng, Yuanzhi Zheng, Wenjing Li, Ruomei Gao, Le Du*, Yujun Wang*. Scale-up potential of photochemical microfluidic synthesis by selective dimension enlarging with agitation of microbubbles. Chemical Engineering Science, 2020, 226, 115862.
[16]Jiaojiao Fan, Yuanzhi Zheng, Yingtian Yang, Le Du*, Yujun Wang*. Enhancement of Ultraviolet B Irradiation with a Photoluminescent Composite Film and Its Application in Photochemical Microfluidic Synthesis. Industrial & Engineering Chemistry Research, 2020, 59, 12870-12878.
[17]Guangsheng Luo*, Le Du, Yujun Wang, Kai Wang. Manipulation and Control of Structure and Size of Inorganic Nanomaterials in Microchemical Systems. Chemical Engineering & Technology, 2019, 42, 1996-2008.
[18]Guangsheng Luo*, Le Du, Yujun Wang, Kai Wang. Recent developments in microfluidic device-based preparation, functionalization, and manipulation of nano- and micro-materials. Particuology, 2019, 45, 1-19.
[19]Le Du, Yang Li, Ruomei Gao, Chun Shen*, Yujun Wang*. Controllability and flexibility in particle-manufacturing of a segmented microfluidic device with passive picoinjection. AIChE Journal, 2018, 64, 3817-3825.
[20]Caijin Zhou, Chun Shen*, Kaiyue Ji, Jiabin Yin, Le Du*. Efficient production of 5-hydroxymethylfurfural enhanced by liquid–liquid extraction in a membrane dispersion microreactor. ACS Sustainable Chemistry & Engineering, 2018, 6, 3992-3999.
[21]Chun Shen, Wuqing Zhou, Hao Yu, Le Du*. Ni nanoparticles supported on carbon as efficient catalysts for steam reforming of toluene (model tar). Chinese Journal of Chemical Engineering, 2018, 26, 322-329.
[22]Caijin Zhou, Jiabin Yin, Cai Wu, Le Du*, Yujun Wang*. Efficient target capture and transport by fuel-free micromotors in a multichannel microchip. Soft Matter, 2017, 13, 8064-8069.
[23]Caijin Zhou, Yujun Wang*, Le Du*, Hongbao Yao. Preparation of highly dispersed SiO2 nanoparticles using continuous gas-based impinging streams. Chemical Engineering Journal, 2017, 327, 734-742.
[24]Jiabin Yin, Chun Shen*, Xinqiang Feng, Kaiyue Ji, Le Du*. Highly Selective Production of p‐Xylene from 2,5-Dimethylfuran over Hierarchical NbOx‐Based Catalyst. ACS Sustainable Chemistry & Engineering, 2017, 6, 1891-1899.
[25]Le Du, Yujun Wang, Jianhong Xu, Chun Shen*, Guangsheng Luo*. In situ dispersion of non-aqueous Fe3O4 nanocolloids by microdroplet coalescence and their use in the preparation of magnetic composite particles. Soft Matter, 2016, 12(23), 5180-5187.
[26]Le Du, Kai Wang, Chun Shen*, Guangsheng Luo*. In situ dispersion of oil-based Ag nanocolloids by microdroplet coalescence and their applications in SERS detection. RSC Advances, 2016, 6(64), 59639-59647.
[27]Le Du, Yujun Wang, Weidong Zhang, Chun Shen*, Guangsheng Luo*. Preparation of nonaqueous silver nanosuspensions by in situ dispersion of the surface-modified nanoparticles. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2016, 501, 114-121.
[28]Le Du*, Yujun Wang, Zhongqi Ren*, Chun Shen, Guangsheng Luo*. Preparation of Au Nanocolloids by in Situ Dispersion and Their Applications in Surface-Enhanced Raman Scattering (SERS) Films. Industrial & Engineering Chemistry Research, 2016, 55, 6783-6791.
[29]Caijin Zhou, Yujun Wang*, Le Du*, Hongbao Yao, Jingchuo Wang, Guangsheng Luo. Precipitation Preparation of High Surface Area and Porous Nanosized ZnO by Continuous Gas-Based Impinging Streams in Unconfined Space. Industrial & Engineering Chemistry Research, 2016, 55, 11943-11949.
[30]Yumei Zhang, Weidong Zhang*, Zhengyu Yang, Junteng Liu, Fushen Yang, Le Du*. Enhancement of fine particle filtration with efficient humidification. Chinese Journal of Chemical Engineering, 2016, 24, 453-459.
[31]Le Du, Yujun Wang, Kai Wang, Guangsheng Luo*. Growth of Aragonite CaCO3 Whiskers in a Microreactor with Calcium Dodecyl Benzenesulfonate as a Control Agent. Industrial & Engineering Chemistry Research, 2015, 54, 7131-7140.
[32]Le Du, Yujun Wang, Kai Wang, Guangsheng Luo*. Effects of nanoparticles with different wetting abilities on the gas–liquid mass transfer. Chemical Engineering Science, 2014, 114, 105-113.
论著专利
专著:
[1]《微化工技术》,第八章《基于微化工过程的纳微材料可控制备》,2020,ISBN 978-7-122-36183-7,化学工业出版社
[2]Composite nanoparticles. Encyclopedia of Microfluidics and Nanofluidics. 2014, DOI: 10.1007/ 978-3-642-27758 -0_243-3,Springer出版社
发明专利:
[1]一种制备纳米二氧化硅的方法. CN101798090B(已授权);
[2]一种制备β-磷酸钙或羟基磷灰石纳米颗粒的方法. CN101811685B(已授权);
[3]一种制备硫酸钡纳米颗粒的方法. CN102167386B(已授权);
[4]一种管式反应器内光化学合成维生素D2、D3的方法. CN109081796B(已授权);
[5]一种管式反应器内光化学反应的微混合系统. CN209138596U(已授权);
[6]一种光源可定制化的光化学合成系统及方法. CN111266069B(已授权);
[7]一种高浓高盐废水零排放的连续处理方法及装置. CN110627150B(已授权);
[8]一种纳米氧化锌的制备方法及纳米氧化锌. CN112777627B(已授权);
[9]一种纳米二氧化钛的制备方法及纳米二氧化钛. CN112645384A.(已授权)。
讲授课程
《化工原理(I)》(面向材料、制药、生工专业本科生)
招生需求
希望有上进心的同学加入团队,尤其欢迎有其他学科特长的同学。招生后,按学生意愿分基础研究型与工程应用型进行培养:基础研究侧重科学规律探索,以发表高水平文章为目标;工程应用侧重工程技术开发与应用,与微化工企业和制药行业领军企业共同培养,以设备和工艺设计为导向,培养应用技术人才。
合作交流
学术界:与国内外从事微化工技术基础和应用研究的课题组开展长期合作,已培养多位毕业生前往ICL、UCD、HKU、清华大学读博。
企业界:与国内多家煤化工企业、石油石化企业、精细化学品生产企业等开展长期合作。
