Curriculum Vitae
Name: Li
Baoqing
Email address: bqli@ustc.edu.cn
Phone call: +86
551 6360 0214;
Address: Dept.
of PMPI, West Campus, 96 Jinzhai Road, USTC, Hefei,
Anhui, China
Education:
Doctor of Engineering 2004-2008,
Precision Instrumentation and Machinery, University of Science and Technology
of China
Master of Engineering 2000-2003,
Testing and Measuring Technology and Instrument, University of Science and
Technology of China
Bachelor
of Engineering 1995-2000,
Testing and Control Technology and Instrument, University of Science and Technology of
China
Employment
History:
Associate
Professor, University of Science and Technology of China, 2016 - now
Visiting Assistant Professor, University of
California, Davis, 2013- 2016
Lecturer, University of Science and Technology of
China, 2008-2016
Research assistant, Hong Kong Polytechnic University,
2004-2006
Area
of Specialization:
Microfluidic technology;
MEMS fabrication technology;
Micro sensor and actuator;
Micro and Nano fabrication by ultra-fast pulse laser
Selected
Publications:
1.
Liu, Kai; Pan, Yang; Wang, Xiaojie; Ma, Tuo; Li, Baoqing*; Chu, Jiaru ; A
low-cost self-dispersing method of droplet array generation enabled by a simple
reusable mask for bioanalysis and bioassays, Analytical and Bioanalytical
Chemistry, 2022, 414: 1141-1149.
2.
Ma, Tuo, Wang, Yousu, Sun Shixin, Pan, Tingrui, Li, Baoqing*, Chu, Jiaru. Size-tunable droplet microfluidic system using an
on-chip microfluidic peristaltic pump. Sensors and Actuators A: Physical, 2022,
334: 113332.
3.
Wang, Yiming; Wang, Xiaojie; Pan, Tingrui; Li, Baoqing; Chu, Jiaru ; Label-free single-cell isolation enabled by microfluidic
impact printing and real-time cellular recognition, Lab on a Chip, 2021,
21(19): 3695-3706.(Cover)
4.
Yang Pan, Tuo Ma, Qi
Meng, Yuxin Mao, Kaiqin
Chu, Yongfan Men, Tingrui
Pan, Baoqing Li*, Jiaru
Chu. Droplet digital PCR enabled by microfluidic impact printing for absolute
gene quantification. Talanta, 2020, 211: 120680.
5.
Sen Li, Jiaru Chu, Baoqing Li, Yu Chang*, Tingrui
Pan*. Handwriting Iontronic Pressure Sensing Origami.
ACS applied materials & interfaces, 2019, 11(49): 46157-46164.
6.
Sen Li, Ning Pan, Zijie
Zhu, Ruya Li, Baoqing Li, Jiaru Chu, Guanglin Li, Yu
Chang*, Tingrui Pan*. All‐in‐One Iontronic Sensing Paper. Advanced Functional Materials,
2019, 29(11): 1807343.
7.
Tuo Ma, Shixin Sun, Baoqing Li*, Jiaru Chu. Piezoelectric peristaltic micropump integrated
on a microfluidic chip. Sensors and Actuators A: Physical, 2019, 292: 90-96.
8.
Mao, Y., Wang, X., Li, X., Li, B.*, & Chu, J.
Modelling on the droplet formation and optimizing of the microfluidic cartridge
used for the microfluidic impact printing. Journal of Micromechanics and
Microengineering, 2019, 29(12), 125016.
9.
Li, X., Mao, Y., Zhu, Z., Zhang, Y., Fang, Z., Wu,
D., ... Li, B.* & Chu, J.. Digital flow rate
sensor based on isovolumetric droplet discretization effect by a three-supersurface structure. Microfluidics and Nanofluidics, 2019, 23(8), 102.
10.
Chen, J., Ma, J., Zuo,
H., Yuan, X., Li, B.*, & Chu, J. Woofer–tweeter deformable mirror driven by
combined actuators with a piezoelectric unimorph and
stack for astronomical application. Applied optics, 2019, 58(9), 2358-2365.
11.
Mao, Yuxin, Yang Pan,
Xuan Li, Baoqing Li*, Jiaru
Chu, and Tingrui Pan*, "High-precision digital
droplet pipetting enabled by a plug-and-play microfluidic pipetting
chip." Lab on a Chip,18, no. 18, 2720-2729, 2018 (Front cover).
12. Jinzhen Fan, Yongfan Men, Kuo Hao Tseng, Yi
Ding, Yunfeng Ding, Fernando Villarreal, Cheemeng Tan, Baoqing Li*, and Tingrui Pan*, Dotette: programmable,high-precision,
plug-and-play droplet pipetting. Biomicrofluidics
12, 034107,2018.
13. Jinzhen Fan, Fernando Villarreal, Brent Weyers, Yunfeng
Ding, Kuo Hao Tseng, Jiannan
Li, Baoqing Li *, Cheemeng
Tan*, and Tingrui Pan*, Multi-dimensional Studies of
Synthetic Genetic Promoters Enabled by Microfluidic Impact Printing, Lab on a chip, 17, 2198-2207, 2017 (Back
Cover).
14. Junjie Chen, Jianqiang
Ma*, Yuxin Mao, Ying Liu, Baoqing
Li*, Jiaru Chu, Experimental
evaluation of a positive-voltage-driven unimorph
deformable mirror for astronomical applications, Optical Engineering, 54(11), 117103-117103, 2015.