胡远渡

博士、高聘教授、博士生导师,硕士生导师

基本信息

办公电话: 电子邮件: huyd@bjtu.edu.cn
通讯地址:北京交通大学理学院教5-5308A 邮编:100044

教育背景

2008 - 2013,华中科技大学,高分子化学与物理,硕博连读;导师:杨亚江 教授,朱锦涛 教授

2004 - 2008,湖北大学,高分子材料与工程,本科学习;导师:徐祖顺

工作经历

2021.05 - 至今,北京交通大学,高聘教授(四级); 2020年10月入选北京交通大学“卓越百人”人才计划;

在加入北京交通大学前分别在德国Merck KGaA旗下EMD Electronics公司(New Jersey Branch, 2020—2021),美国哈佛大学(2014—2020),美国圣母大学(University of Notre Dame,2013—2014)开展产品研发和学术科研工作。

研究方向

  • 材料表面技术及功能材料
  • 光电材料及其应用
  • 材料工程
  • 物理与交叉学科

招生专业

  • 材料科学与工程硕士
  • 材料工程硕士
  • 物理学博士

科研项目

1. 光子晶体微球的精确制备及性能研究,卓越百人(第四层次)人才启动经费,2021-2023,主持

2. 层状结构多功能化光子晶体微粒的构筑及性能研究,基本科研业务费,2023-2025,主持

3. 可控刻蚀法进行光子晶体微粒的精确构筑聚合物分子工程国家重点实验室开放课题基金,2024.01-2024.11,主持

4. 涂层微观结构与性能研究,自然科学基金横向项目,2024.07-2024.10,主持

5. 多禁带光子晶体微粒的精确构筑与结构调控,先进材料重点实验室课题,2024-2025,主持

6. 聚合物微胶囊结构与性能调控研究,广东省高分子先进制造技术及装备重点实验室课题,2024-2025,主持

7. 复合微胶囊的精确构筑及其减振降噪性能研究,湖北省重点实验室课题,2024-2025,主持

8.  Top-down Synthesis of an Ex-nova Chemical Artificial Living System,Harvard University-Repsol联合项目,2010-至今(连续资助),> 3000万美元,参与(时间段:2014-2020

9.  Fluid Dynamics of bacterial aggregation and formation of biofilm streamers, NSF Career Awards(美国国家自然科学基金委杰青项目, University of Notre Dame),2012-201422.9万美元,参与(时间段:2013-2014

10  Chemically Amplified Ultrathick Positive photoresist. EMD Electronics - Samsung U.S.A (默克电子(美国)公司-三星电子(美国)公司合作项目),约30万美元,参与(时间段:2020-2021)

11  珲春南站办理危险货物运行试验安全评估报告,自然科学基金横向项目,2022-2024,参与

12.  高端植物油抗磨剂的合成工艺研究,自然科学基金横向项目,2024-2025,参与

13.  具有感知能力的耐高温4d打印柔性蒙皮材料定制,红果园省部级"企事业"(新), 参与 



教学工作

本科生课程:纳米材料与技术,材料化学,高分子材料,大学物理实验等专业课和实验课

硕士研究生课程:无机合成化学

博士研究生课程:功能复合材料

论文/期刊

      长期从事于将微加工(如微流控技术(Microfluidics),光刻(Photolithography)等)结合功能高分子的合成, 胶体颗粒(包括无机、有机和无机/有机杂化等)合成以及自组装来精确构筑具有多层次结构多重性能的微结构颗粒,如响应性光子晶体微球,高分子微胶囊,高分子囊泡,高分子胶体体(Colloidosomes), 多壳层响应性水凝胶微胶囊等。迄今为止,已经在领域内主流SCI期刊上发表研究论文20余篇,申请美国发明专利一项并已经获得公开,在工业界工作的另外一篇专利正在提交申请阶段,且与该专利工作相关的产品已经在Merck公司形成一个产品出售(Photosensitive Patterning Materials (merckgroup.com): AZ 8100 series)。截止至今,在已发表的第一作者研究工作中,单篇引用次数最高140余次,单篇正面它引最高140余次,它引来自于全世界各地的著名研究机构,包括美国麻省理工学院、英国剑桥大学、德国马普所等。多篇研究论文或者被媒体大幅度报导(如发表在Langmuir上的工作被https://phys.org/(该网站年浏览量超过百万次)网站以整篇幅报导:'Microfluidics' enables production of 'shape-controllable microgels' sought for medicine, research (phys.org)),或者被杂志选为封面(Macromol. Rapid Commun. 3/2017 - Hu - 2017 - Macromolecular Rapid Communications - Wiley Online Library),或被其他杂志被大幅度的正面点评(如以第一作者发表在Biomicrofluidics-2012 Langmuir-2012上的工作分别被剑桥大学João T. Cabral教授课题组撰写的第四章节Design and Fabrication of Polymer Microparticles and Capsules Using Microfluidics和韩国Shin-Hyun Kim教授课题组撰写的Lab ChipLab Chip, 2016, 16, 3415)杂志上正面大篇幅引用和评论,另外更多被大篇幅正面引用报导的例子)和报导。

同行评审论文(通讯作者和第一作者论文)

  • 独立开展研究工作后(2021年后)

1. J. Chen, R. Yu, K. Wang, Z. Zhang, A. Ardekani* and Y. Hu*. Spherical Magnetic Fe-Alginate Microgels Fabricated by Droplet-Microfluidics Combining with an External Crosslinking Approach and the Study of Their pH Dependant Fe3+Release Behaviors. Chinese Journal of Polymer Science, Accepted, 2024
2. 
Y. Bai, X. Du, Z. Cai* and Y. Hu*. Advances in the Construction of Photonic Structures with Dual Stopbands and Beyond. Journal of materials chemistry C, 2024, 671, 457-468.

3. J. Chen, H. Shen, Y. Heng, S. Wang, A. Ardekani, Y. Yang and Y. Hu* Droplet Microfluidics-Assisted Fabrication of Shape Controllable Iron-Alginate Microgels with Fluorescent Property. Macromolecular Rapid Communications, 2024, 240084.

4. R. Li, Y. Hu; Y. Xu; Wang, C. Wang; X. Li; S. Liang; B. Liu; W. Li. A Dimerized Non-fused Electron Acceptor based on Thieno[3,4-c]pyrrole-4,6-dione Core for Organic Solar Cells, ACS Applied Materials&Interfaces, 2024, 16, 22256–22264.

5. X. Du, C. Li, J. Wang, Z. Li, J. Zhu*, Y. Yang, Y. Hu*. Multifunctional Photonic Microobjects with Asymmetric Response in Radial Direction and Their Anticounterfeiting Performance, Journal of Colloid and Interface Science, 2024, 671, 457-468. (Front Cover, 被选为前封面文章)

6. Y. Hu*, A. Ardekani, J. Zhu, Y. Yang, J. P-Mercader. Recent Progress in the Construction of Photonic Microobjects Assisted by Microfluidics. Proposal Submitted, 2023

7. Q. Wang, C. Zhou, Y. Zheng, H. Pang, S. Li, Y. Hu*, Q. Cui*. Dual-bandgap Janus photonic crystals from single emulsion droplets: rapid preparation and structurally controllable strategies. Cryst. Growth Des. 2024,  9, 3657–3663.

8. P. Li, H. Pang, Y. Zheng, Q. Cui, C. Shang, Y. Xiao, T. Hui, Y. Hu*. Composite Photonic Microobjects with Anisotropic Photonic Properties from a Controlled Wet Etching Approach. Colloids and Surfaces A: Physicochemical and Engineering Aspects2024, 688, 133618.

9. H. Li, C. Dai*, Y. Hu*. Hydrogels for Chemical and Biosensings. Macromol. Rapid Commun. 2023, 202300474.

10. Y. Hu*. Controlled Evaporation-Induced Phase Separation of Droplets Containing Nanogels and Salt Molecules. RSC Adv., 2022, 12, 27977 - 27986.

11. C. Zhou, S. Zhang, T. Hui, Q, Cui*, Y. Hu*. Microfluidics-Assisted Fabrication of Dual Stopband Photonic Microcapsules and Their Applications for Anticounterfeiting. Polymers, 2022, 14(19), 3954.


其它合作论文:

12. B. Xu, J. Wang*, C. Cai, W. Xin, L. Wei*, Q.Yang, B. Peng, Y. Hu, J. Li*, X. Wang. Construction of Laminated Luminescent Solar Concentrator “Smart” Window Based on Thermoresponsive Polymer and Carbon Quantum Dots. Crystals, 2022, 12, 1612.


  • 独立开展研究工作前(2021年前)

1. Y. Hu,* J. Tresback, J. Peréz-Mercader.* Preparation of ruthenium-functionalized microgels through the intermolecular crosslinking of two functionalized polymers within droplets and study of their chemical/photo-active behaviors. Polym. Degrad. Stab2020, 181, 109345. (*通讯作者

2. Y. Hu, C. Li, J. Wang, X. Jia, J. Zhu,* Q. Wang, H. Wang, Y. Yang.* Osmosis Manipulable Morphology and Photonic Property of Microcapsules with Colloidal Nano-in-micro Structure. J. Colloid Interface Sci. 2020, 574, 337-346. (*通讯作者

3. Y. HuJ. Pérez-Mercader.* Microcapsules with Distinct Dual-Layer Shells and Their Applications for the Encapsulation, Preservation and Control and Release of Hydrophilic Small Molecules. ACS Appl. Mater. Interfaces. 2019, 11(44), 41640-41648. (*通讯作者

4. Y. Hu,* J. Pérez-Mercader.* Microfluidics Assisted Synthesis of Crosslinked Colloidosomes with Multisensitive Behaviors: a Potential Platform for Photo Memory Device and Blue Light-Triggered Release Vehicle. ACS Appl. Nano Mater. 2018, 1(7), 3346–3354. (*通讯作者

5. Y. Hu,* J. Pérez-Mercader.* Microfluidics Fabrication of Self-Oscillating Microgel Clusterswith Tailored Temperature-Responsive Properties using Polymersomes as ‘Microreactors’. Langmuir, 2017, 33 (49), 14058–14065. (*通讯作者

6. Y. Hu,* J. Pérez-Mercader.* Controlled Synthesis of Uniform, Micrometer-Sized Ruthenium-Functionalized Poly (N-Isopropylacrylamide) Gel Particles and their Application to the Catalysis of the Belousov–Zhabotinsky Reaction. Macromolecular Rapid Communications, 2017, 381600577.( Macromolecular Rapid Communications 选为 back cover http://onlinelibrary.wiley.com/doi/10.1002/marc.20 1770011/full) (*通讯作者

7. Y. Hu,* J. Pérez-Mercader.* Microfluidic Fabrication of Polymersomes Enclosing an Active Belousov-Zhabotinsky Reaction: Effect on Their Stability of Solute Concentrations in the External Media. Colloids and Surfaces B: Biointerfaces2016, 146, 406–414. (*通讯作者

8. Y. Hu, S. Wang, A. Abbaspourrad, A. M. Ardekani. Fabrication of Shape Controllable Janus Alginate/pNIPAAm Microgels via Microfluidics Technique and Off-Chip Ionic Cross-Linking. Langmuir, 2015, 31 (6), 1885–1891. ( https://phys.org/网站在 https://phys.org/news/2015 -02-microfluidics-enables-production-shape-controllable-microgels.html 作为亮点文章大篇幅      Purdue University             https://www.purdue.edu/newsroom/releases/2015/Q1/ microfluidics-enables-production-of-shape-controllable-microgels-sought-for-medicine,-research.html ). 

9. Y. Hu, G. Azadi, A. M. Ardekani. Microfluidic Fabrication of Shape-Tunable Alginate Microgels: Effect of Size and Impact Velocity. Carbohydrate Polymers, 2015, 120, 38-45. 

10. Y. Hu, J. Wang, C. Li, Z. Li, R. Liang, Q. Wang, H. Wang, J. Zhu, Y. Yang. Non-Spherical Hollow Microgels with Uniform Sizes and Tunable Shapes from Microfluidic-Assisted Approach. Science of Advanced Materials, 2015, 7(5), 902-908. 

11. Y. Hu, J. Wang, C. Li, Q. Wang, H. Wang, J. Zhu, Y. Yang. Janus Photonic Crystal Microspheres: Centrifugation-Assisted Generation and Reversible Optical Property. 

Langmuir, 2013, 29 (50), 15529–15534. 

12. Y. HuJ. WangH. WangQ. Wang, J. ZhuY. Yang. Microfluidic Fabrication and Thermo-reversible Response of Core/Shell Photonic Crystal Microspheres Based on 

Deformable Nanogels. Langmuir2012, 28, 17186–17192. 

13. Y. Hu, Q Wang, J. Wang, J. Zhu, H. Wang, Y. Yang. Shape Controllable Microgel Particles Prepared by Microfluidic Combining External Ionic Crosslinking. Biomicrofluidics2012.6(2): p.026502. ( AIP Biomicrofluidics 作为高亮文章重点介绍同时该论文被选为 2012   日出版的 Virtual Journal of Nanoscale Science & Technology . 8th of the top 20 most read articles June to September 2012). 



专著/译著

专利

已经网上公开及正在申请的发明专利: 

1. 专利名:MICROFLUIDIC MULTICHANNEL DEVICE. 发明人:J. Pérez-Mercader, Y. Hu
US Patent Application US20200140628A1; 申请单位:Harvard College. 网上公开链接: https://patents.google.com/patent/US2020014 0628A1/en 
2.  专 利 名 : Positive Tone Ultra Thick Photoresist Composition. W. Liu, Y. Hu, C. Chen. United States Patent Application, 2022. 

软件著作权

获奖与荣誉

社会兼职

Youth Editorial Board Members(2024.01-2025.12) for the journal Advanced Bionics, A recently launched journal  with webpage at: https://www.sciencedirect.com/journal/advanced-bionics

* Guest editor, Polymers, Special Issue: Multifunctional Polymer Microstructure Particles”, 2022-2023. Link: https://www.mdpi.com/journal/polymers/special_issues/Multifunct_Polym_Microstruct_Part

* Co-Guest editorPolymers, Special Issue: Polymer Colloids: Preparation and Application", 2023. Link: https://www.mdpi.com/journal/polymers/special_issues/6Q0O1B0B6D


* 为多个杂志,包括 Advanced Materials, ACS Applied Materials&Interfaces, Coordination Chemistry Reviews, Lab ChipLangmuir, Carbohydrate PolymersFood Hydrocolloids, Soft Matter, Sensors and Actuators 

B: Chemical, Dyes and Pigments, Sensors & Actuators:A. Physical 等作为独立审稿人

* Polymers2023 国际学术会议科学组委会成员(Organizing Scientific Committee):https://scientificcollegium.net/polymerscience-engineering-conference/organizing-scientific-committee/