分别于2005年、2010年在清华大学化学工程系获得学士和博士学位。2012年起从事教学和科研工作，2014年晋升副教授，2015-2016年在麻省理工学院化工系作访问学者。主讲《化工原理》和《胶体与界面科学》课程。

1. 微尺度动态界面特性与规律

针对多相微分散过程中吸附、传质、化学反应引发的动态界面现象开展系统研究，发展微尺度动态表界面张力实验方法，建立基于LBM的动态界面张力和界面吸附量模拟方法，揭示多相微反应过程的介尺度效应和机制。

2. 流动化学与微反应器有机电合成

针对高端和精细化学品的绿色、安全合成，探索基于微反应器的连续流动合成原理和方法研究，揭示微反应器工程科学原理并实现产业化应用，将电化学有机合成与微化工技术相融合，开发电能驱动的高端化学品制造技术与工艺。

3. 微化工系统与人工智能

围绕化工过程的智能化，与过程系统工程研究所合作探索人工智能方法在微化工技术开发和产业化过程中的应用，发展基于机器学习算法的微分散检测技术，建立基于人工智能模型的微化工开发和应用方案。

1. 自然科学基金面上项目，电化学微通道反应器内气液分散规律和模型化，2022.1 - 2025.12

2. 国家重点研发计划课题，微反应器强化硝化反应流程再造技术与示范，2021.12 – 2024.11

3. 国家重点实验室自主课题，电合成微通道反应器内气液分散规律研究，2020.7 - 2022.6

4. 山东省重大科技创新工程项目，微反应系统在荧烷类热敏染料连续流合成中的产业化开发与示范，2019.9 – 2022.8

5. 自然科学基金面上项目，微尺度下动态界面张力的基本规律和模型化，2018.1 - 2021.12

6. 清华大学自主科研计划，微反应器自由基聚合反应过程研究，2016.1 - 2018.12

7. 自然科学基金-云南联合基金重点项目（子课题），湿法冶金微流体萃取的基础理论研究，2014.1 - 2017.12

8. 国家重点实验室自主课题，微尺度液滴气泡聚并机制研究，2012.12 - 2014.12

9. 自然科学基金青年基金项目，气-液-液三相微尺度分散机制与模型化研究，2012.1 - 2014.12

10. 全国优秀博士论文资助项目，微尺度液滴聚并基本规律研究，2012.1 - 2016.12

2022

1. Liang X, Li M, Wang K^*, Luo GS. Determination of time-evolving interfacial tension and ionic surfactant adsorption kinetics in microfluidic droplet formation process. J COLLOID INTERF SCI. 2022; 617: 106-117.

2. Liang X, Zhang JYZ, Li M, Wang K^*, Luo GS. Dynamic interfacial tension and adsorption kinetics of nonionic surfactants during microfluidic droplet formation process. CHEM ENG J. 2022; 445: 136658.

3. Zheng SY, Wang K^*. Electrosynthesis of tetrabenzylthiuram disulfide via flow reactors. CHEM ENG SCI. 2022; 257: 117717.

4. Zhang SY, Liang X, Huang X, Wang K^*, Qiu T^*. Precise and fast microdroplet size distribution measurement using deep learning. CHEM ENG SCI. 2022; 247: 116926.

5. Liu D^#, Yan JY^#, Wang K^*, Wang YD^*, Luo GS. Continuous synthesis of ultrasmall core-shell upconversion nanoparticles via a flow chemistry method. NANO RES. 2022; 15: 1199-1204.

2021

1. Liang X, Wang XY, Lu SY, Wang K^*, Luo GS. Pressure drop analysis for the droplet break-up flow in a locally constrictive microchannel. CHEM ENG SCI. 2021; 230: 116190.

2. Zheng SY, Wang K^*, Luo GS. Microfluidic electrosynthesis of thiuram disulfides. GREEN CHEM. 2021; 23: 582-591.

3. Zheng SY, Yan JY, Wang K^*. Engineering research progress of electrochemical microreaction technology-A novel method for electrosynthesis of organic chemicals. ENGINEERING. 2021; 7: 22-32.

4. Zong Y, Li M, Wang K^*. Outflow boundary condition of multiphase microfluidic flow based on phase ratio equation in lattice Boltzmann method. PHYS FLUIDS. 2021; 33: 73304. (Editor’s Pick)

5. Cheng K^#, Lu SY^#, Wang K^*, Luo GS. Green and sustainable synthesis of poly(δ-valerolactone) with a TBD catalyzed ring-opening polymerization reaction. REACT CHEM ENG. 2021; 7: 76-83. (Back Cover)

2020

1. Lin XY, Wang K^*, Zhou BY, Luo GS^*. A microreactor-based research for the kinetics of polyvinyl butyral (PVB) synthesis reaction. CHEM ENG J. 2020; 383: 123181.

2. Cui YJ^#, Li YK^#, Wang K^*, Deng J, Luo GS^*. High-throughput preparation of uniform tiny droplets in multiple capillaries embedded stepwise microchannels. J FLOW CHEM. 2020; 10: 271-282.

3. Sui JS, Yan JY, Wang K^*, Luo GS. Efficient synthesis of lithium rare-earth tetrafluoride nanocrystals via a continuous flow method. NANO RES. 2020; 13: 2837-2846.

4. Sui JS^#, Yan JY^#, Liu D, Wang K^*, Luo GS^*. Continuous synthesis of nanocrystals via flow chemistry technology. SMALL. 2020; 16: 1902828.

5. Deng J, Zou PC, Wang K^*, Luo GS. Continuous-flow synthesis of (E)-2-hexenal intermediates using a two-stage microreactor system. J FLOW CHEM. 2020; 10: 661-672.

2019

1. Song J^#, Zhang SL^#, Wang K^*, Wang YD. Synthesis of million molecular weight polyacrylamide with droplet flow microreactors. J TAIWAN INST CHEM ENG. 2019; 98: 78-84.

2. Liu D, Jing Y, Wang K^*, Wang YD^*, Luo GS. Reaction study of alpha-phase NaYF₄:Yb,Er generation via a tubular microreactor: Discovery of an efficient synthesis strategy. NANOSCALE. 2019; 11: 8363-8371.

3. Lu SY, Wang K^*. Kinetic study of TBD catalyzed delta-valerolactone polymerization using a gas-driven droplet flow reactor. REACT CHEM ENG. 2019; 4: 1189-1194. (Cover)

2018

1. Riaud A^#, Zhang H^#, Wang XY, Wang K^*, Luo GS^*. Numerical study of surfactant dynamics during emulsification in a T-junction microchannel. LANGMUIR. 2018; 34: 4980-4990.

2. Qin K, Wang K^*, Luo R, Li Y, Wang T^*. Dispersion of supercritical carbon dioxide to [Emim][BF₄] with a T-junction tubing connector. CHEM ENG PROCESS. 2018; 127: 58-64.

3. Xie P, Wang K^*, Zhang JS, Hu YP, Luo GS^*. In situ removal of HBr via microdroplets for high selectivity bromobutyl rubber synthesis in a microreaction system. IND ENG CHEM RES. 2018; 57: 10883-10892.

4. Wang K^*, Zhang HM, Shen Y, Adamo A, Jensen KF^*. Thermoformed fluoropolymer tubing for in-line mixing. REACT CHEM ENG. 2018; 3: 707-713.

2017

1. Liu D, Wang K^*, Wang Y, Wang YD^*, Luo GS. A simple online phase separator for the microfluidic mass transfer studies. CHEM ENG J. 2017; 325: 342-349.

2. Xie P, Wang K^*, Wang PJ, Xia Y, Luo GS^*. Synthesizing bromobutyl rubber by a microreactor system. AIChE J. 2017; 63: 1002-1009.

3. Wang K, Luo GS^*. Microflow extraction: A review of recent development. CHEM ENG SCI. 2017; 169: 18-33.

4. Yang L, Liu GT, Luo S, Wang K^*, Luo GS^*. Investigation of dynamic surface tension in gas-liquid absorption using a microflow interfacial tensiometer. REACT CHEM ENG. 2017; 2: 232-238.

5. Lin XY, Yan S, Zhou BY, Wang K^*, Zhang JS, Luo GS^*. Highly efficient synthesis of polyvinyl butyral (PVB) using a membrane dispersion microreactor system and recycling reaction technology. GREEN CHEM. 2017; 19: 2155-2163. (Back Cover)

6. Wang K, Li LT, Xie P, Luo GS^*. Liquid-liquid microflow reaction engineering. REACT CHEM ENG. 2017; 2: 611-627.

2016-2006

1. Zhou QQ, Sun Y, Yi ST, Wang K^*, Luo GS. Investigation of droplet coalescence in nanoparticle suspensions by a microfluidic collision experiment. SOFT MATTER. 2016; 12: 1674-1682.

2. Wang K^*, Zhang LM, Zhang WL, Luo GS. Mass-transfer-controlled dynamic interfacial tension in microfluidic emulsification processes. LANGMUIR. 2016; 32: 3174-3185.

3. Qiu L, Wang K^*, Zhu S, Lu YC, Luo GS. Kinetics study of acrylic acid polymerization with a microreactor platform. CHEM ENG J. 2016; 284: 233-239.

4. Qin K, Wang K^*, Luo R, Li Y, Wang T^*. Interfacial tension and wetting properties of 1-ethyl-3-methylimidazolium tetrafluoroborate in carbon dioxide, from atmospheric pressure to supercritical state. J SUPERCRIT FLUID. 2016; 116: 83-89.

5. Qin K, Wang K^*, Li Y, Kong FH, Wang T^*. High-pressure phase behavior of 1-ethyl-3-methylimidazolium tetrafluoroborate and carbon dioxide system. RSC ADV. 2015; 5: 32416-32420.

6. Li Y, Wang K^*, Qin K, Wang T^*. Beckmann rearrangement reaction of cyclohexanone oxime in sub/supercritical water: byproduct and selectivity. RSC ADV. 2015; 5: 25365-25371.

7. Wang K^*, Qin K, Wang T, Luo GS. Ultra-thin liquid film extraction based on a gas-liquid-liquid double emulsion in a microchannel device. RSC ADV. 2015; 5: 6470-6474.

8. Wang K^*, Zhang JS, Zheng C, Dong C, Lu YC, Luo GS^*. A consecutive microreactor system for the synthesis of caprolactam with high selectivity. AIChE J. 2015; 61: 1959-1967.

9. Wang K^*, Qin K, Lu YC, Luo GS, Wang T. Gas/liquid/liquid three-phase flow patterns and bubble/droplet size laws in a double T-junction microchannel. AIChE J. 2015; 61: 1722-1734.

10. Lin XY, Wang K^*, Zhang JS, Luo GS^*. Process intensification of the synthesis of poly(vinyl butyral) using a microstructured chemical system. IND ENG CHEM RES. 2015; 54: 3582-3588.

11. Wang XY, Riaud A, Wang K^*, Luo GS^*. Pressure drop-based determination of dynamic interfacial tension of droplet generation process in T-junction microchannel. MICROFLUID NANOFLUID. 2015; 18: 503-512.

12. Wang PJ, Wang K^*, Zhang JS, Luo GS^*. Preparation of poly(p-phenylene terephthalamide) in a microstructured chemical system. RSC ADV. 2015; 5: 64055-64064.

13. Wang XY, Wang K^*, Riaud A, Wang X, Luo GS^*. Experimental study of liquid/liquid second-dispersion process in constrictive microchannels. CHEM ENG J. 2014; 254: 443-451.

14. Riaud A, Zhao SF, Wang K^*, Cheng Y, Luo GS. Lattice-Boltzmann method for the simulation of multiphase mass transfer and reaction of dilute species. PHYS REV E. 2014; 89: 533085.

15. Wang K, Lu YC, Luo GS^*. Strategy for scaling-up of a microsieve dispersion reactor. CHEM ENG TECHNOL. 2014; 37: 2116-2122.

16. Wang K, Xie L, Lu YC^*, Luo GS^*. Generating microbubbles in a co-flowing microfluidic device. CHEM ENG SCI. 2013; 100: 486-495.

17. Wang K, Xie L, Lu YC^*, Luo GS^*. Generation of monodispersed microdroplets by temperature controlled bubble condensation processes. LAB CHIP. 2013; 13: 73-76.

18. Riaud A, Wang K^*, Luo GS^*. A combined Lattice-Boltzmann method for the simulation of two-phase flows in microchannel. CHEM ENG SCI. 2013; 99: 238-249.

19. Wang K^*, Lu YC, Tostado CP, Yang L, Luo GS^*. Coalescences of microdroplets at a cross-shaped microchannel junction without strictly synchronism control. CHEM ENG J. 2013; 227: 90-96.

20. Wang K^*, Lu YC, Qin K, Luo GS^*, Wang T. Generating gas-liquid-liquid three-phase microflows in a cross-junction microchannel device. CHEM ENG TECHNOL. 2013; 36: 1047-1060.

21. Wang K^*, Lu YC, Yang L, Luo GS^*. Microdroplet coalescences at microchannel junctions with different collision angles. AIChE J. 2013; 59: 643-649.

22. Wang K^*, Lu YC, Xia Y, Shao HW, Luo GS^*. Kinetics research on fast exothermic reaction between cyclohexanecarboxylic acid and oleum in microreactor. CHEM ENG J. 2011; 169 :290-298.

23. Wang K^*, Lu YC, Xu JH, Luo GS^*. Droplet generation in micro-sieve dispersion device. MICROFLUID NANOFLUID. 2011; 10: 1087-1095.

24. Wang K, Lu YC, Xu JH, Tan J, Luo GS^*. Generation of micromonodispersed droplets and bubbles in the capillary embedded T-junction microfluidic devices. AIChE J. 2011; 57: 299-306.

25. Wang K, Lu YC, Tan J, Yang BD, Luo GS^*. Generating gas/liquid/liquid three-phase microdispersed systems in double T-junctions microfluidic device. MICROFLUID NANOFLUID. 2010; 8: 813-821.

26. Wang K, Lu YC, Shao HW, Luo GS^*. Measuring enthalpy of fast exothermal reaction with micro-reactor-based capillary calorimeter. AIChE J. 2010; 56: 1045-1052.

27. Wang K, Lu YC, Xu JH, Luo GS^*. Determination of dynamic interfacial tension and its effect on droplet formation in the T-shaped microdispersion process. LANGMUIR. 2009; 25: 2153-2158.

28. Wang K, Lu YC, Xu JH, Tan J, Luo GS^*. Liquid-liquid micro-dispersion in a double-pore T-shaped microfluidic device. MICROFLUID NANOFLUID. 2009; 6: 557-564.

29. Wang K, Lu YC, Shao H, Luo GS^*. Improving selectivity of temperature-sensitive exothermal reactions with microreactor. IND ENG CHEM RES. 2008; 47: 4683-4688.

30. Wang K, Lu YC, Shao HW, Luo GS^*. Heat-transfer performance of a liquid-liquid microdispersed system. IND ENG CHEM RES. 2008; 47: 9754-9758.

31. Wang K, Wang YJ, Chen GG, Luo GS^*, Wang JD. Enhancement of mixing and mass transfer performance with a microstructure minireactor for controllable preparation of CaCO₃ nanoparticles. IND ENG CHEM RES. 2007; 46: 6092-6098.

32. Wang K, Lu YC, Xu JH, Gong XC, Luo GS^*. Reducing side product by enhancing mass-transfer rate. AIChE J. 2006; 52: 4207-4213.

1. 微尺度有机合成反应的传递强化机制与规律, 中国化工学会，基础科学研究成果奖一等奖，2021-1

2. Emerging Investigator, Journal of Flow Chemistry, 2020

3. 微通道内纳米颗粒对液滴聚并的影响规律，中国科协优秀科技论文，2019

4. 未来学者，全球华人化工学者研讨会，2019

5. Class of Influential Researchers, Industrial & Engineering Chemistry Research, 2018

6. Emerging Investigator, Reaction Chemistry & Engineering, 2017

7. 侯德榜化工青年科技奖，中国化工学会，2015

8. 非均相微反应过程的微型化基础研究，全国优秀博士论文，2012

9. 非均相微反应过程的微型化基础研究，北京市优秀博士论文，2011

硕士（毕业时间）

隋金凇（2020），卢诗尧（2019），张圣龙（2019），张皓（2019），陈扬（2018），周倩倩（2016），仇禄（2016）

本科（毕业课题时间）：

宗毅（2021），程亦平（2020），安星磊（2020），赵旭（2019），李东焕（2019），王瀚琳（2018），周元昊（2017），董哓锐（2017），王乙汀（2016），宋劲（2015），孙悦（2014），易诗婷（2013），王一帆（2013）

访问学生

张议文，北京化工大学，2020-2021

程凯，延边大学，2018

科研助理

祁星瑞，2020-2021

张礼明，2016-2020