冀健龙

职称:副院长/副教授

主要研究方向:微纳器件与系统,包括:有机晶体管、神经形态芯片、微纳传感器

Email:jijianlong@tyut.edu.cn

基本信息:冀健龙,男,1984年10月生,山西太原人,工学博士,副教授、博士生导师。

研究方向:微纳器件与系统

教育背景及工作经历

【学习经历】

2019.07-2021.07,******特色医学中心,博士后。

2010.09-2014.07,太原理工大学(清华联培),工学博士。

2007.09-2010.07,太原理工大学,工学硕士。

2003.09-2007.07,太原理工大学,工学学士。

【工作经历】

2024.10-至今, 太原理工大学,集成电路学院,副院长。

2022.12-2024.02,忻州经济开发区管理委会,副主任(挂职)。

2021.09-2022.07,清华大学,访问学者。

2018.01-2019.01,北卡罗来纳州立大学,访问学者。

2014.07-至今, 太原理工大学,集成电路学院,教师。

学术兼职:

1. 中国仪器仪表学会微纳器件与系统技术分会委员

2. 中国微米纳米学会青年工作委员会委员

荣誉获奖:

荣誉称号

1. “三晋英才”支持计划青年优秀人才

科研获奖

1. 山西省自然科学一等奖

科研项目及科研成果

主持课题

【国自然项目】

国家自然科学基金面上项目(项目批准号:52175542)、国家自然科学基金青年科学基金(项目批准号:51705354)

【省部级项目】

山西省自然科学基金面上项目(项目批准号:20210302123136),重庆市自然科学基金面上项目(项目批准号:cstc2020jcyj-msxmX0002),山西省自然科学基金青年项目(项目批准号:2015021092),山西省高等学校科技创新项目(项目批准号:183290224-S),山西省专利转化计划项目(项目批准号:202304012),山西省科技合作交流专项项目(项目批准号:202304041101032),山西省留学人员科技活动择优资助项目(项目批准号:20240007),山西省回国留学人员科研资助项目(项目批准号:2024-062),中国博士后科学基金面上项目(项目批准号:2020M673646)

【专利转化项目】ZL201910182023.1、ZL201910181300.7

发表论文

1. H. Li, Z. Jin, X. Jiang, M. An, J.-L. Ji*, and D. Huang*, “Influence of reaction cell electrodes on organic electrochemical transistors,” Applied Physics Letters, vol. 124, no. 9, pp. 093509, 2024.

2. J.-L. Ji, J. Liu, Y. Wang, F. Zhang, M. Zhao, S. Yan, X. Guo, W. Zhang, S.-B. Sang*, X. Chai*, and Q. Sun*, “Liquid-solid heterojunction constructing bio-sensory floating-gate OECTs,” Nano Energy, vol. 128, pp.109962, 2024.

3. X. Chen, J.-L. Ji*, Y. Peng, Z. Gao, M. Zhao, B. Tang*, and Y. Liu*, “Flexible pH sensors based on OECTs with a BTB dye-embedded ion-gel gate dielectric,” Journal of Materials Chemistry C, vol. 11, no. 23, pp. 7722-7731, 2023.

4. Y. Peng, X. Jin, P. Zeng, M. Zhao, Z. Gao*, J.-L. Ji*, X. Li, and W. Chen, “CsPbBr3 QDs Employed as Gate to Fabricate an Artificial Photosynapse,” ACS Applied Electronic Materials, vol. 5, no. 9, pp. 4996-5004, 2023.

5. J.-L. Ji, Z. Wang, F. Zhang, B. Wang, Y. Niu, X. Jiang, Z. Y. Qiao, T. L. Ren, W. Zhang, S. Sang*, Z. Cheng*, and Q. Sun*, “Pulse electrochemical synaptic transistor for supersensitive and ultrafast biosensors,” InfoMat, vol. 5, no. 11, pp.1-15, 2023.

6. Y. Chen, D. Han, D*. Li, H. -T. Wang, X. He, Z. Liu, X. Liu, S.-B. Sang, and J.-L. Ji*, “High-performance nitrogen dioxide gas sensor for ppb-level detection based on GaN nanoshuttles,” Microchemical Journal, vol. 185, pp.108183, 2023.

7. R. Liu, Y.-B. Peng, Q. Huang, X. Yang, Y.-M. Jia*, Y. Du*, and J.-L. Ji*, “Current-Voltage Characteristics of Organic Electrochemical Transistors Considering Effects of Gate Polarization and Adsorbed Charge,” Acta Physica Sinica, vol. 50, no. 6, pp. 878-888,2022.

8. S.-J. Li, Z.-X. Wang, Y. Niu, B. Wang, S.-B. Sang, W.-D. Zhang, Y. Gao, and J.-L. Ji*, “I-V characteristics and voltage dependence of pH-sensitive organic electrochemical transistors,” Acta Physica Sinica, vol. 71, no. 13, pp.138501, 2022.

9. J.-L. Ji, H. Wang, R. Liu, X. Jiang, Q. Zhang, Y. Peng, S.-B. Sang*, Q. Sun*, and Z. L. Wang*, “Dual-liquid-gated electrochemical transistor and its neuromorphic behaviors,” Nano Energy, vol. 87, pp.106116, 2021.

10. J.-L. Ji, Y. Fu, J. Wang, P.-Y. Chen, D. Han, Q. Zhang, W. Zhang, S.-B. Sang*, X. Yang*, and Z. Cheng*, “Bipolar electrodeposition of organic electrochemical transistor arrays,” Journal of Materials Chemistry C, vol. 8, no. 33, pp. 11499-11507, 2020.

11. J.-L. Ji, J. Wang, L. Wang, Q. Zhang, Q. Duan, S.-B. Sang*, Q. Huang*, S. Li*, W. Zhang, and X. Jiang, “Dynamic-coupling analyses of cells localization by the negative dielectrophoresis,” Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, vol. 235, no. 2, pp. 402-411, 2020.

12. J.-L. Ji, J. Zhang, J. Wang, Q. Huang, X. Jiang, W. Zhang, S.-B. Sang*, X. Guo*, and S. Li*, “Three-dimensional analyses of cells’ positioning on the quadrupole-electrode microfluid chip considering the coupling effect of nDEP, ACEO, and ETF,” Biosensors and Bioelectronics, vol. 165, pp.112398, 2020.

13. Y. Ge, J.-L. Ji*, Q. Zhang, Z. Yuan, R. Wang, W. Zhang, and S.-B. Sang*, “Unraveling the intrinsic magnetic property of triangular zigzag edge bilayer graphene nanoflakes: A first-principles theoretical study,” Chemical Physics Letters, vol. 730, pp. 326-331, 2019.

14. Y. Ge, J.-L. Ji*, Q. Zhang, Z. Yuan, A. Jian, X. Yang, G. Xiao, W. Zhang, and S.-B. Sang*, “Zero-energy-state-oriented tunability of spin polarization in zigzag-edged bowtie-shaped graphene nanoflakes under an electric field,” Nanotechnology, vol. 30, no. 8, pp.085201, 2019.

15. J.-L. Ji, M. Li, Z. Chen, H. Wang, X. Jiang, K. Zhuo, Y. Liu, X. Yang, Z. Gu, S.-B. Sang*, and Y. Shu*, “In situ fabrication of organic electrochemical transistors on a microfluidic chip,” Nano Research, vol. 12, no. 8, pp. 1943-1951, 2019.

16. Y. Liu*, Y. Wu, K. Li, J. Wang, C. Zhang, J.-L. Ji*, and W. Wang, “Amorphous SnS nanosheets/graphene oxide hybrid with efficient dielectric loss to improve the high-frequency electromagnetic wave absorption properties,” Applied Surface Science, vol. 486, pp. 344-353, 2019.

17. J.-L. Ji, Y.-L. Liu, Y. Ge, S.-D. Xie, X. Zhang, S.-B. Sang*, A.-Q. Jian, Q.-Q. Duan, Q. Zhang, and W.-D. Zhang, “Simulation Study on the Controllable Dielectrophoresis Parameters of Graphene,” Chinese Physics Letters, vol. 34, no. 4, pp.046601, 2017.

18. J.-L. Ji, C. Qiao, Y. Liu, W. Zhang, S.-B. Sang*, X. Yang, A. Jian, Q. Duan, Q. Zhang, and Y. Liu*, “Utilizing Fullerenols as Surfactant for Carbon Nanotubes Dispersions Preparation,” Journal of Materials, vol. 2017, pp. 1-7, 2017.

19. J.-L. Ji, P. Li, S.-B. Sang*, W. Zhang, Z. Zhou, X. Yang, H. Dong, G. Li, and J. Hu, “Electrodeposition of Au/Ag bimetallic dendrites assisted by Faradaic AC-electroosmosis flow,” AIP Advances, vol. 4, no. 3, pp.031329, 2014.

20. J.-L. Ji, Z. Zhou*, X. Yang*, W. Zhang*, S.-B. Sang, and P. Li, “One‐Dimensional Nano‐Interconnection Formation,” Small, vol. 9, no. 18, pp. 3014-3029, 2013.

授权专利

1. 低功耗全波段光通信芯片及其制备方法,2024.01.23,中国,ZL202311492026.8

2. 一种基于有机半导体的阻抗流式细胞仪,2023.08.11,中国,ZL202310672809.8

3. 一种多参数跨尺度生化传感器芯片及其使用方法,2023.05.23,中国,ZL202310244710.8

4. 一种生物传感器及其制作方法,2023.01.10,中国,ZL202011062167.2

5. 一种无标识生物传感器及其制作方法,2023.01.10,中国,ZL202011062164.9

6. 一种基于PEDOT:PSS电化学晶体管的微流控芯片及其制备方法,2021.06.11,中国,ZL201910181300.7

7. 一种基于聚吡咯电化学晶体管的微流控芯片及其制备方法,2021.04.02,中国,ZL201910181299.8

8. 一种高通量、高内涵药物筛选微流控芯片及其制备方法,2021.06.11,中国,ZL201910182823.1

9. 一种高通量微孔板药物筛选芯片及其制备方法,2020.12.22,中国,ZL201910182022.7

10. 一种具有高集成度的自供电压力传感器,2019.07.16,中国,ZL201710266746.0

11. 一种基于压电技术的自供电无线液压用压力传感器,2019.05.21,中国,ZL201710266146.4

12. 用于无标识高内涵药物筛选的微流控芯片及其制作方法,2018.12.28,中国,ZL201710077109.9

13. 基于MEMS技术的无线无源流量传感器,2019.01.04,中国,ZL201610500974.5

14. 一种无线无源煤岩界面识别装置,2018.01.23,中国,ZL201610244796.4

15. 一种用于S0I光波导的侧壁粗糙度检测方法和装置,2017.03.22,中国,ZL201410794625.X

16. 具有纳米枝晶拉曼基底的微流控芯片的制作方法,2016.08.24,中国,ZL201410657689.5

【软著】

1. 电化学防熔断系统软件V1.0,2018SR192699

2. 类突触器件及类脑芯片测试软件V1.0,2021SR2007463

著 作

1. 交流电沉积法及其在微纳器件中的应用,西安电子科技大学出版社,ISBN:978-7-5606-6483-8