同济大学材料学院黄佳教授

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姓名：    黄佳
职称：    教授，博士生导师
电子邮箱：  huangjia@tongji.edu.cn
办公地点：    材料楼451室
电话：    15000851061
传真：  
课题组主页：    http://web.tongji.edu.cn/~huangjia/

研究方向
有机半导体
柔性电子器件
能源材料
传感器

学习工作经历
2002年        本科毕业于中国科学技术大学材料科学与工程系
2004年      硕士毕业于美国威廉玛丽学院
2009年        博士毕业于美国约翰霍普金斯大学
2009-2012年        美国马里兰大学
2012年    入选第二批国家计划
2013年至今 同济大学 教授

所获奖励
2013年    上海市浦江人才计划
2014年    上海市嘉定区青年领军人才
2014年     第五届中国青年科协常务理事
2015年      同济青年五四奖章
2015年     上海市青年岗位能手称号
2015年        同济大学“我心目中的好导师”

授课情况
080226 材料概论 （本科）
功能高分子 （研究生）
“可持续发展与未来”跨学科大型公共课 (面对全校)

代表性论文与著作
部分代表性论文:
学术期刊论文 SELECTED PUBLICATIONS
1.Wu, Xiaohan; Ma, Yan, Zhang, Guoqian; Chu,Yingli; Du, Juan; Zhang, Yin; Li, Zhuo; Duan, Yourong; Fan, Zhongyong*; Huang, Jia*. Thermally Stable, Biocompatible and Flexible Organic Field-effect Transistors and Their Application in Temperature Sensing Arrays for Artificial Skin. Advanced Functional Materials, (2015) 25, pp2138-2146
2.J. Peng, Y. Chen, X. Wu, Q. Zhang, X. Chen, Y. Chen*, J. Huang*, Z. Liang,* Correlating Molecular Structures with Transport Dynamics in High-Efficiency Small Molecule Organic Photovoltaics  ACS Appl. Mater. Interfaces (2015) 7, 13137–13141
3.Yin Zhang§, Juan Du§, Xiaohan Wu, Guoqian Zhang, Yingli Chu, Dapeng Liu, Yixin Zhao*, Ziqi Liang*, and Jia Huang*. Ultrasensitive Photodetectors Based on Island-Structured CH3NH3PbI3 Thin Films (2015) Under Revision
4.Huang, Jia; Allen L. Ng, Yanmei Piao, Chien-Fu Chen, Alexander A. Green, Chuan-Fu Sun, Mark C. Hersam, Cheng S. Lee, and YuHuang Wang. Covalently Functionalized Double-Walled Carbon Nanotubes Combine High Sensitivity and Selectivity in the Electrical Detection of Small Molecules. Journal of the American Chemical Society, (2013), 135, pp 2306–2312.
5.Huang, Jia; Hongli Zhu, Yuchen Chen, Colin Preston, Kathleen Rohrbach, John Cumings, and Liangbing Hu. Highly Transparent and Flexible Nanopaper Transistors. ACS Nano (2013) 7, 2106–2113.
6.M Yamamoto, O Pierre-Louis, J Huang, MS Fuhrer, TL Einstein, WG Cullen. The Princess and the Pea at the Nanoscale: Wrinkling and Delamination of Graphene on Nanoparticles.Physical Review X (2012) (4), 041018
7.Huang, J.*; Yin, Z.G.; and Zheng, Q.D. Applications of ZnO in organic and hybrid solar cells.Energy & Environmental Science. (2011) 4, 3861.
8.Huang, J.; *Hines, D.; Williams, E.; Fuhrer, M.; Cumings, J. et. al. Polymeric Semiconductor/Graphene Hybrid Field-effect Transistors. Organic Electronics. (2011) 12, 1471.
9.Huang, J.; Dawidcyk, T.; Jung, B.J.; Mason A. and Katz H.E. Response diversity and dual response mechanism of organic field-effect transistors with dinitrotoluene vapor. Journal of Materials Chemistry. (2010) 20, 2644.
10.Someya, T.; Dodabalapur, A.; Huang, J. See, KC.; and Katz, H.E. Chemical and physical sensing by organic semiconductor-based devices. Advanced Materials. (2010) 22, 3799.
11.Katz, H.E. and Huang, J. Thin Film Organic Electronic Devices. Annual Review of Materials Research. (2009) 39, 71.
12.Sun, J.; Jun, B.J.; Lee, T.; Berger, L.; Huang, J.; Katz, H.E., et. al. "Tunability of Mobility and Conductivity over Large Ranges in PQT12/Insulating Polymer Composites". ACS Appl. Mat. & Interf.(2009) 1, 412
13.Huang, J.; Sun, J.; Katz, H.E. Monolayer-dimensional 5,5’-Bis(4-hexylphenyl)-2,2’-bithiophene Transistors and Chemically Responsive heterostructures. Advanced Materials. (2008) 20, 2567.
14.Zheng, Q.D.; Huang, J.; Sarjeant, A.; Katz, H.E. Pyromellitic Diimides: Minimal Cores for High Mobility n-channel Transistor Semiconductors, Journal of the American Chemical Society.(2008) 130, 14410
15.Takao Someya, Bholanath Pal, Jia Huang, and Howard E. Katz “Organic Semiconductor Devices with Enhanced Field and Environmental Responses ”. MRS Bulletin. (2008) 33, 690
16.Huang, J.; Miragliotta, J.; Becknell, A.; Katz, H.E. Hydroxy-terminated organic semiconductor blend based field effect transistors for phosphonate vapor Journal of the American Chemical Society. (2007) 129, 9366.
17.Ye, H.K.; Huang, J.; Park J.R.; Katz H.E.; and Gracias, D.H. Correlations between Electrical Properties and SFG Spectra of Organic Field Effect Transistors. Journal of Physical Chemistry C. (2007) 111, 13250.
18.See, K.; Huang, J.; Katz, H.E. et al. Performance Requirements and Mechanistic Analysis of Organic Transistor based Phosphonate Gas Sensors. Organic Semiconductors in Sensor Applications. Edited by Malliaras, G. (2007)
19.Ye, H.K.; Abu, A.; Huang, J.; Katz, H.E.; and Gracias, D. Probing organic field-effect transistors during operation using surface sum-frequency generation. Journal of the American Chemical Society. (2006) 128, 6528.
20.Katz, H.E., Huang, Jia. Organic Semiconductor-based Chemical Sensors. Monograph.Organic electronics: materials, manufacturing and applications. Edited by Klauk, H..(2006)
21.J.G. Cheng, S.W. Zha, J. Huang, X. Liu, G. Meng. Sintering behavior and electrical conductivity of Ce0.9Gd0.1O1.95 powder prepared by the gel-casting process, Materials Chemistry and Physics 78 (2003) 791.
著作
·See, K., Huang, J., et al. Performance Requirements and Mechanistic Analysis of Organic Transistor-based Phosphonate Gas Sensors. Organic Semiconductors in Sensor Applications. Edited by G. Malliaras (2008)
·Katz, H.E., Huang, Jia. Organic Semiconductor-based Chemical Sensors. Monograph.Organic electronics: materials, manufacturing and applications. Edited by Klauk, H..(2006)
·Wu, Xiaohan, Huang, Jia*. Chemical and Biological Sensors based on Nanowire Transistors. Bio-Inspired Nanomaterials and Applications. Edited by: Donglu Shi, Published by World Scientific Publishing. (2015)
·Huang, Jia*, Application of Nano-structured Materials and Devices in Chemical and Biological Sensing. Published by World Scientific Publishing. (2015),主编

manyibu

肩并肩有机二极管结构传感器实现微量固体化学物质的灵敏检测

对各类有害化学物质的检测在环境控制、食品安全、医疗卫生、工业生产以及国防军事等很多领域中都具有重要的意义。基于有机晶体管的传感器具有低成本、易制备、器件微型化、便携、高灵敏度和高选择性以及柔性等一系列特点和优势，因而在上述领域具有较大的应用潜力。有机晶体管的化学传感器对气态和液态化学物质的检测已具有较多的研究，然而对固体粉末样品的直接、快速检测一直是此类传感器研究领域的难题。基于传统场效应，晶体管传感器的载流子在场电压的作用下累积于半导体层，在靠近介电层界面的几个分子层的厚度内形成导电沟道。使用该传感器探测化学分析物时，分析物分子需要首先在有机半导体薄膜内长距离地扩散才能接触导电沟道内的半导体分子，然后起到改变器件输出信号的作用。气态和液态的化学物质相对容易扩散，而固体化学物质难以快速地扩散到导电沟道中。基于此，同济大学黄佳教授课题组对传统有机晶体管的结构进行衍生化，设计制备了新型的基于肩并肩有机二极管结构的传感器，实现了对微量固体化学物质在粉末样品状态下的灵敏检测。使用该传感器，他们可以实现对亿分之一浓度三聚氰胺粉末样品的监测，与此同时还具有一定的分析物选择性。

不同于场效应晶体管，这种肩并肩的二极管结构能使固体粉末分析物置于传感器上时，分析物与有机半导体薄膜表面的相互作用能显著影响载流子的浓度与传输速度，从而改变传感器的输出信号。使用这种肩并肩二极管传感器来检测粉末样品中含有的微量三聚氰胺时，器件对1 ppm的三聚氰胺样品表现出超过40%的输出电流降幅，以此估算的传感器对三聚氰胺的检测浓度下限能达到ppm以下量级。研究还发现，有机半导体材料本身的分子结构和侧链结构对该传感器的性能具有显著的影响，传感器对不同固体粉末样品的检测信号也表现出明显的不同，因此具有一定的传感选择性。该工作首次实现了对固体粉末分析物的直接快速检测，而且这一器件的设计策略具有广泛的适用性，可由此开发出针对多种固体粉末分析物的低成本便携式微型传感器。

这一成果近期发表在Journal of the American Chemical Society 上，文章的通讯作者为同济大学材料科学与工程学院的黄佳教授。

该论文作者为：Jia Huang, Guoqian Zhang, Xingang Zhao, Xiaohan Wu, Dapeng Liu, Yingli Chu and Howard E. Katz

Direct Detection of Dilute Solid Chemicals with Responsive Lateral Organic Diodes

J. Am. Chem. Soc., 2017, 139, 12366, DOI: 10.1021/jacs.7b06223