姓名：梁文峰  职称：教授
性别：男
出生日期：1984/09
所在专业：机械电子工程
硕士生指导教师：是
博士生指导教师：是
E-mail：liangwf@sjzu.edu.cn
联系电话：024-24692169

研究方向：微纳机器人；生物机械系统；微流控系统；

***********教育经历及工作经历*********

2014.07-现在           云顶集团  机械工程学院  机械设计制造及其自动化系
2017.11-2018.11     Duke University  机械工程与材料科学系  国家公派访问学者
2014.11-2017.11     中国科学院沈阳自动化研究所  控制学科与工程  博士后
2013.02-2013.12     香港城市大学  机械工程系   研究助理
2008.09-2014.07     中国科学院沈阳自动化研究所  机械电子工程  博士（硕博连读）

***********科研项目***********

主持的科研项目：

(1) 基于声表面波辐射力的活细胞机械特性自动获取方法研究（2020/01-2023/12）。编号：61973224，国家自然科学基金，经费：58万；在研
(2) 微纳机器人多场操控与生物医学应用（2019/07-2021/06）。编号：2019-KF-01-15，辽宁省科技厅，经费：10万；在研
(3) 活体单细胞电/力学本征信息自动获取方法研究（2016/01-2018/12）。编号：61503258，国家自然科学基金，经费：20万；已结题
(4) 基于光诱导介电泳的活体单细胞本征信息自动获取方法研究（2016/07-2018/06）。编号：201602614，辽宁省科技厅，经费：5万；已结题
(5) 细胞多维信息获取与模型联立（2016/01-2018/12）。编号：2016Z01，机器人学国家重点实验自主课题，经费：20万；已结题
(6) 面向单细胞力学信息自动获取的微纳操控方法研究（2017/11-2019/10）。编号：CXPY2017012，云顶集团科研创新培育计划项目，经费：4万；已结题
(7) 基于微纳操控的免标记细胞物性测量和分离方法研究（2015/09-2016/08）。编号：201509，机器人学国家重点实验室，经费：5万；已结题；

曾参与的科研项目——

(1) 基于光诱导电液动力学的癌细胞分离研究。香港研究资助局基金，经费78万港币；
(2) 微纳操控与类生命机器人。编号：61925307，国家自然科学基金，经费400万；
(3) 纳米操作机器人。编号：61522312，国家自然科学基金，经费150万；
(4) 基于系统科学的细胞多维信息实时自动获取与分析方法研究。编号：61433017，国家自然科学基金，经费300万；
(5) 基于光诱导的可编程一体化微纳制造方法研究。编号：51461165501，国家自然科学基金，经费200万；
(6) 纳米操作机器人技术在癌症靶向治疗中的应用研究。编号：60904095，国家自然科学基金，经费26万；

***********发表论文***********

[1] Wenfeng Liang*, Xieliu Yang, Junhai Wang, Yuechao Wang, Hemin Zhang, Wenguang Yang, and Lianqing Liu*. Label-free characterization of different kinds of cells using optoelectrokinetic-based microfluidics. Optics Letters, 45(8), 2454-2457, 2020. (SCI: 000526401600083)
[2] Wenfeng Liang*, Haohao Shi, Xieliu Yang, Junhai Wang, Wenguang Yang, Hemin Zhang*, and Lianqing Liu*. Recent advances in AFM-based biological characterizations and applications at multiple levels. Soft Matter, 16(39), 8962-8984, 2020. (SCI: 000577734200001)
[3] Wenfeng Liang*, Jing Liu, Xieliu Yang, Qi Zhang, Wenguang Yang, Hemin Zhang*, and Lianqing Liu*. Microfluidic-based cancer cell separation using active and passive mechanisms. Microfluidics and Nanofluidics, 24(4), 26, 2020. (SCI: 000521150500001)
[4] Wenfeng Liang*, Xieliu Yang, Junhai Wang, Yuechao Wang, Wenguang Yang, and Lianqing Liu*. Determination of Dielectric Properties of Cells using AC Electrokinetic-based Microfluidic Platform: A Review of Recent Advances. Micromachines, 11(5), 513, 2020. (SCI: 000540761400063)
[5] Wenfeng Liang, Lianqing Liu*, Junhai Wang, Xieliu Yang, Yuechao Wang, Wen Jung Li*, and Wenguang Yang. A Review on Optoelectrokinetics-Based Manipulation and Fabrication of Micro/Nanomaterials. Micromachines, 11(1), 78, 2020. (SCI: 000514309100077)
[6] Wenguang Yang*, Shuxiang Cai, Yibao Chen, Wenfeng Liang, Youbin Lai, Haibo Yu*, Yuechao Wang, and Lianqing Liu*. Modular and Customized Fabrication of 3D Functional Microgels for Bottom-Up Tissue Engineering and Drug Screening. Advanced Materials Technologies, 1900847, 2020. (SCI: 000517404600001)
[7] Wenfeng Liang, Lianqing Liu*, Hemin Zhang, Yuechao Wang, and Wen Jung Li*. Optoelectrokinetics-based microfluidic platform for bioapplications: A review of recent advances. Biomicrofluidics, 13(5), 051502, 2019. (SCI: 000494825200005)
[8] Wenfeng Liang, Lianqing Liu*, Yuechao Wang, Gwo-Bin Lee, and Wen Jung Li*. Rapid assembly of carbon nanoparticles into electrical elements by optically-induced electroosmotic flow. IEEE Transactions on Nanotechnology, 17(5), 1045-1052, 2018. (SCI: 000443975800024)
[9] Wenfeng Liang, Yuliang Zhao, Lianqing Liu*, Yuechao Wang, Wen Jung Li*, and Gwo-Bin Lee. Determination of cell membrane capacitance and conductance via optically induced electrokinetics. Biophysical Journal, 113(7), 1531-1539, 2017. (SCI: 000412551200016) (Cover)
[10] Xieliu Yang, Xihui Niu, Zhu Liu, Yuliang Zhao, Guanglie Zhang, Wenfeng Liang*, and Wen Jung Li*. Accurate extraction of the self-rotational speed for cells in an electrokinetics force field by an image matching algorithm. Micromachines, 8(9), 282, 2017. (Corresponding author) (SCI: 000411523200024)
[11] Yunwu Yu*, Yan Wang, Tianwei Li, Wenfeng Liang, Chun Li, Wanyang Niu, and Lili Gao. Synthesis, properties and gas separation performance of poly (arylene ether sulfone) containing imide pendant groups. RSC Advances, 7(67), 42468-42475, 2017. (SCI: 000409147500059)
[12] Wenfeng Liang, Yuechao Wang, Hemin Zhang, and Lianqing Liu. Characterization of the self-rotational motion of stored red blood cells by using optically-induced electrokinetics. Optics Letters, 41(12), 2763-2766, 2016. (SCI: 000378065900024/EI: 20162602546714)
[13] Wenfeng Liang, Ke Zhang, Xieliu Yang, Lianqing Liu*, Haibo Yu, and Weijing Zhang. Distinctive translational and self-rotational motion of lymphoma cells in an optically induced non-rotational alternating current electric field. Biomicrofluidics, 9(1), 014121, 2015. (SCI: 000350546900021)
[14] Wenfeng Liang, Yuliang Zhao, Lianqing Liu*, Yuechao Wang, Zaili Dong, Wen Jung Li*, Gwo-Bin Lee, Xiubin Xiao, and Weijing Zhang. Rapid and label-free separation of Burkitt’s lymphoma cells from red blood cells by optically-induced electrokinetics. PLoS One, 9(3), e90827, 2014. (SCI: 000332485800056)
[15] Wenfeng Liang, Lianqing Liu, Sam Hok-Sum Lai, Yuechao Wang, Gwo-Bin Lee, and Wen Jung Li*. Rapid assembly of gold nanoparticle-based microstructures using optically-induced electrokinetics. Optical Materials Express, 4(11), 2368-2380, 2014. (SCI: 000344962100016)
[16] Wenfeng Liang, Na Liu, Zaili Dong, Lianqing Liu, John D. Mai*, Gwo-Bin Lee, and Wen Jung Li*. Simultaneous separation and concentration of micro- and nano-particles by optically induced electrokinetics. Sensors and Actuators A: Physical, 193, 103-111, 2013. (SCI: 000315838800013)
[17] Wenfeng Liang, Shue Wang, Zaili Dong, Gwo-Bin Lee, and Wen J. Li*. Optical spectrum and electric field waveform dependent optically-induced dielectrophoretic (ODEP) micro manipulation. Micromachines, 3(2), 492-508, 2012. (SCI: 000325015500021)
[18] 梁文峰，刘娜，刘连庆*，王越超，李文荣*，李国宾，于海波，张伟京。面向微纳米自动化操控的光诱导电液动力学关键技术。科学通报，58(S2)，194-199，2013。
[19] 梁文峰*，曲艳丽，董再励。基于交流电渗流的碳纳米颗粒自动化装配技术。科学通报，57(14)，1270-1278，2012。
[20] Na Liu, Wenfeng Liang, Lianqing Liu*, Yuechao Wang, John D. Mai, Gwo-Bin Lee, and Wen J. Li*. Extracellular-controlled breast cancer cell formation and growth using non-UV patterned hydrogels via optically-induced electrokinetics. Lab on a Chip, 14(7), 1367-1376, 2014. (SCI: 000332454600015)
[21] Na Liu, Wenfeng Liang, John D. Mai, Lianqing Liu*, Gwo-Bin Lee, and Wen J. Li*. Rapid fabrication of nanomaterial electrodes using digitally-controlled electrokinetics. IEEE Transactions on Nanotechnology, 13(2), 245-253, 2014. (SCI: 000333084400012)
[22] Feifei Wang, Haibo Yu, Wenfeng Liang, Lianqing Liu, John D. Mai*, Gwo-Bin Lee, and Wen Jung Li*. Optically induced electrohydrodynamic instability-based micro-patterning of fluidic thin films. Microfluidics and Nanofluidics, 16(6), 1097-1106, 2014. (SCI: 000338835000011)
[23] Chih-Hung Wang, You-Hsun Lee, Hsin-Tzu Kuo, Wen-Feng Liang, Wen-Jung Li, and Gwo-Bin Lee*. Dielectrophoretically-assisted electroporation using light-activated virtual microelectrodes for multiple DNA transfection. Lab on a Chip, 14(3), 592-601, 2014. (SCI: 000328911400018)
[24] Yuliang Zhao, Wenfeng Liang, Guanglie Zhang*, John D. Mai, Lianqing Liu, Gwo-Bin Lee, and Wen J. Li*. Distinguishing cells by their first-order transient motion response under an optically-induced dielectrophoretic force field. Applied Physics Letters, 103(18), 183702, 2013. (SCI: 000327816000039)
[25] Long-Ho Chau, Wenfeng Liang, Florence Wing Ki Cheung, Wing Keung Liu*, Wen Jung Li*, Shih-Chi Chen, and Gwo-Bin Lee. Self-rotation of cells in an irrotational AC E-Field in an opto-electrokinetic chip. PLoS One, 8(1), e51577, 2013. (SCI: 000313429800009)
[26] Mengxing Ouyang, Wing Ki Cheung, Wenfeng Liang, John D. Mai, Wing Keung Liu*, and Wen Jung Li*. Inducing self-rotation of cells with natural and artificial melanin in a linearly polarized alternating current electric field. Biomicrofluidics, 7(5), 054112, 2013. (SCI: 000326877600014)
[27] Shue Wang, Wenfeng Liang, Zaili Dong, Vincent G. B. Lee, and Wen J. Li*. Fabrication of micrometer- and nanometer-scale polymer structures by visible light induced dielectrophoresis (DEP) force. Micromachines, 2(4), 431-442, 2011. (SCI: 000208781900005)