张敏，集团深圳研究生院澳门京新葡萄官网副教授，博士生导师，深圳市海外高层次人才“孔雀计划”B 类人才，薄膜晶体管与先进显示实验室副主任。国际电气与电子工程师学会 IEEE 高级会员，国际信息显示学会 SID 会员，多个国际知名学术期刊审稿人。香港科技大学电子及计算机工程学系博士，西安交通大学微电子系硕士及学士。2006 年博士毕业加入香港半导体业界从事集成电路先进器件的设计开发；2012 年加入澳门京新葡萄官网(中国)集团有限公司。作为项目主持人承担和完成国家重点研发计划课题、国家自然科学基金、深圳市科创委创新创业专项、基础研究布局项目等10余项。作为课题第二负责人或项目骨干，参与国家重大专项课题、国家重点研发计划、广东省重点科技项目等10多项。已发表学术论文137余篇，专利授权18项。多次受邀担任国际会议组委、分会场主席和邀请报告。2015年获集团校级优秀班主任，2022年获集团教学优秀奖等奖励。

目前主要研究课题包括：柔性与可拉伸电子（器件与电路集成）、碳基纳米电子（器件与机理）、生物电子集成（生物传感器及系统集成）、类神经突触器件（器件与应用集成）、可穿戴器件（类皮肤传感器及能源器件）、先进显示（微显示VR芯片及柔性显示）。

1. 国家重点研发计划（课题负责人）；

2. 国家自然科学基金-面上项目；

3. 深圳市基础研究（学科布局）项目；

4. 深圳市高等院校稳定支持计划-重点项目；

5. 企业合作项目。

1.  国家自然科学基金-青年科学基金项目；

2.  深圳市基础研究（学科布局）项目；

3.  深圳市海外高层次人次创新创业项目（孔雀技术创新）；

4.  深圳市基础研究（自由探索）项目多项；

5.  深圳市战略性新兴产业发展专项资金项目；

6.  企业合作项目。

      1. 国家重点研发计划项目；

2. 广东省省级科技计划项目；

3.  深圳市重点实验室项目。

BOOK CHAPTERS

        [1]  C. Yang, C. Zhou, M. Zhang, Nanocarbon Electronics, Jenny Stanford Publishing, July 31, 2020, ISBN 9789814877114.

        [2]  M. Zhang, C. Du, Q. Huang, Z. Liao, Y. Deng, W. Huang, and X. Wang, Chapter Carbon Nanotube Transistors in Nanocarbon Electronics, Jenny Stanford Publishing, 2020.

        [3]  M. Zhang, S. Zhang, M. Zhang, Q. Huang, C. Xie, and N. Li, Chapter Graphene Transistors in Nanocarbon Electronics, Jenny Stanford Publishing, 2020.

        [4]  Y. Chai, M. H. Sun, Z. Y. Xiao, Y. Li, M. Zhang, Philip C. H. Chan, Chapter Aligned Carbon Nanotubes for Interconnect Application, Carbon Nanotube and Graphene, CRC press, 2013.

TUTORIAL

[1] M. Zhang, “Nanocarbon-Based Flexible and Stretchable Electronics,” 5^th IEEE International Flexible Electronics Technology Conference, San Jose, USA, August 13-16, 2023. (Tutorial)

IMPORTANT TALKS

[1] M. Zhang, “碳基可拉伸多模态神经形态电子皮肤”, Flexible electronics Technology and Application Innovation Forum, Suzhou, China, May 20-22, 2023.

[2] M. Zhang, “柔软智能电子皮肤赋能显示”, International conference on Display Technology(ICDT), Nanjing, China, March 31-April 4, 2023.

[3] M. Zhang, “Stretchable multimodal neuromorphic electronic devices”, 2^nd Flexible Optoelectronic Materials and Intelligent Sensing Development Forum, Shenzhen, China, November 19-21, 2022.

[4] M. Zhang, “Stretchable neuromorphic electronics,” 2022 Cross-Strait and Hong Kong and Macao Young Scientists Intelligent Wearable Technology Innovation Forum, Hangzhou, China, November 5-7, 2022.

[5] M. Zhang, “Stretchable synaptic transistors based on carbon nanotubes,” 4^th International Flexible Electronics Technology Conference, Qingdao, China, August 21-24, 2022.

[6] M. Zhang, “Soft thin film transistors and synaptic devices,” 2021 Cross-Strait and Hong Kong and Macao Young Scientists Intelligent Wearable Technology Innovation Forum, Suzhou, China, October 30-November 1, 2021.

[7] M. Zhang, “All-carbon flexible and stretchable thin film transistors for integration”, 16^th International Transistor Conference, Shanghai, China, October 20-22, 2021.

[8] M. Zhang, “Intrinsic stretchable thin film transistor based on carbon nanotubes,” 2020 Cross-Strait and Hong Kong and Macao Young Scientists Intelligent Wearable Technology Innovation Forum, Shenzhen, China, December 14, 2020.

[9] M. Zhang, “High-performance intrinsically soft thin film transistors,” 11^th International Conference on Computer Aided Design for Thin-Film Transistor Technologies, Virtual Conference, November 9-10, 2020.

[10] M. Zhang, “A dual-gate IGZO Source-Gated transistor based on field modulation by TCAD simulation,” IEEE 15^th International Conference on Solid-State & Integrated Circuit Technology, Kunming, China, November 3-6, 2020.

[11] M. Zhang, “Applying viscous shear stress to align single-walled carbon nanotubes,” 4^th IEEE Electron Devices Technology and Manufacturing Conference, Penang, Malaysia, April 6-21, 2020.

[12] M. Zhang, “Flexible and stretchable devices based on carbon materials,” 2019 Shenzhen-Hong Kong-Macao Micron and Nanotechnology Innovation Forum, Shenzhen, China, December 21, 2019.

[13] M. Zhang, C. Du, Z. Zhang, Q. Huang, J. Zhang, Q. Wang, H. Jiao, “Carbon based integratable soft thin film transistors,” Conference on Organic Field Effect Transistor, Shenzhen, China, December 12-15, 2019.

[14] M. Zhang, C. Du, J. Zhang, Z. Zhang, Q. Wang, Q. Huang, “Carbon based thin film transistors for advanced displays,” International Meeting on Information Display, Gyeongju, Korea, August 27-30, 2019.

[15] M. Zhang, “Carbon based wearable devices for soft electronics,” IEEE International Conference on Nanotechnology, Macau, China, July 22-26, 2019.

[16] M. Zhang, “Carbon based flexible and stretchable devices for wearable system,” 5^th International Symposium of Flexible and Stretchable Electronics, Shenzhen, China, June 29-30, 2019.

[17] M. Zhang, “Carbon based devices for flexible wearable systems,” IEEE International Conference on Electron Devices and Solid-State Circuits, Xi'an, China, June 12-14, 2019.

[18] M. Zhang, Q. Wang, Q. Huang, Z. Liao, C. Du, “Asymmetric Langmuir-Blodgett and hydrophilization process to realize density-controllable carbon nanotube array on flexible and stretchable substrates,” IEEE International Conference on Nano/Micro Engineered and Molecular Systems, Bangkok, Thailand, April 11-14, 2019.

[19] M. Zhang, C. Du, J. Zhang, Z. Zhang, Q. Wang, Q. Huang, “Carbon based thin film transistors for high drivability and high flexibility,” International Conference on Display Technology, Kunshan, China, March 26-29, 2019.

[20] M. Zhang, Y. Deng, H. Wang, S. Zhang, K. Zhu, C. Du, Y. Gao, “Carbon based TFTs and stretchable devices,” 9^th International Conference on Computer Aided Design for Thin-Film Transistor Technologies, Shenzhen, China, November 16-18, 2018.

[21] M. Zhang, S. Zhang, L. Wen, H. Wang, K. Zhu, C. Xie, “Carbon-Ecoflex nanofins for high linearity strain sensor,” 23^rd Annual Joint Workshop on Advanced Electronic Technology and Application, Jeju, Korea, October 14, 2018.

SELECTED JOURNAL PUBLICATIONS

[1] Q.Ren¹, L.Jiang¹, S. Ma, T. Li, Y. Zhu, R. Qiu, Y. Xing, F. Yin, Z. Li, X. Ye*, Y. Zhang* and M. Zhang*, “Multi-body Biomarker Entrapment System: An All-encompassing Tool for Ultrasensitive Disease Diagnosis and Epidemic Screening,” Advanced Materials, 2023. DOI: 10.1002/adfm.202305379

[2] J. Zhang¹, W. Wang¹, J. Zhu, J. Wang, C. Zhao, T. Zhu, Q. Ren, Q. Liu, R. Qiu, M. Zhang*, X. Wang, H. Meng, K-C Chang, S. Zhang, and M. Chan, “Ultra-Flexible Monolithic 3D Complementary Metal-Oxide-Semiconductor Electronics,” Advanced Functional Materials, 2023, DOI: 10.1002/adfm.202305379.

[3] R. Qiu, J. Wang, Q. Ren, W. Huang, J. Zhu, D. Liu, X. Gao, W. Wang, Q. Liu, M. Zhang*, “Bilingual Bidirectional Stretchable Self-healing Neuristors with Proprioception,” ACS Nano, Vol. 17, No. 13, pp. 12652–12662, 2023.

[4] D. Liu^, W. Wang, J. Zhang, Q. Ren, L. Fan, Y. Wang, Y. Zhang, M. Zhang*, “A universal method for extracting and quantitatively analyzing bias-dependent contact resistance in carbon-nanotube thin-film transistors,” Advanced Electronic Materials, Vol. 9, No. 3, P. 2201148, 2023.

[5] S. Ma^, Q. Ren, L. Jiang, Z. Liu, Y. Zhu, J. Zhu, Y. Zhang,* and M. Zhang*, “A triple-aptamer tetrahedral DNA nanostructures based carbon-nanotube-array transistor biosensor for rapid virus detection,” Talanta, 2023. (Accept)

[6] Y. Huang^, D. Liu¹, X. Gao, J. Zhu, Y. Zhang, M. Zhang*, “Flexible liquid-based continuous direct-current tribovoltaic generators enable self-powered multi-modal sensing,” Advanced Functional Materials, Vol. 33, No. 1, P. 220948, 2022.

[7] Y. Zhang^, D. Liu, Q. Huang, Q. Ren, L. Fan, C. Du, S. Zhang, and M. Zhang*, “Mixed-Dimensional van der Waals engineering for charge transfer enables wafer-level flexible electronics,” Advanced Functional Materials, Vol. 32, No. 36, P. 2205111, 2022.

[8] Y. Huang^, D. Liu, T. Zhu, Y. Zhang, L. Fan, J. Liu*, M. Zhang*, “A mechanically tunable electromagnetic wave harvester and dual-modal detector based on quasi-static van der Waals heterojunction,” Nano Energy, Vol. 99, 2022.

[9] Y. Wang^, D. Liu, Y. Zhang, L. Fan, Q. Ren, S. Ma, and M. Zhang*, “Stretchable temperature-responsive multi-modal neuromorphic electronic skin with spontaneous synaptic plasticity recovery,” ACS Nano, Vol. 16, No. 5, pp. 8283-8293, 2022.

[10] S. Ma^, Y. Zhang¹, Q. Ren, X. Wang, J. Zhu, F. Yin, *, Z. Li*, M. Zhang*, “Tetrahedral DNA nanostructure based biosensor for high-performance detection of circulating tumor DNA using all-carbon nanotube transistor,” Biosensors and Bioelectronics, Vol. 197, P.113785, 2022. (The first author is my postdoctor)

[11] Q. Huang^, J. Wang¹, C. Li, J. Zhu, W. Wang, Y. Huang, Y. Zhang, H. Jiao, S. Zhang, H. Meng, M. Zhang*, X. Wang*, “Intrinsically flexible all-carbon-nanotube electronics enabled by a hybrid organic-inorganic gate dielectric” npj Flexible Electronics, Vol. 6, No. 1, p. 61, 2022.

[12] Z. Zhang^, C. Xie, J. Zhang, M. Chan and M. Zhang*, “Tunable stretchable strain sensors enabled by patterned ecoflex-vertical aligned carbon nanotube arrays and pre-stretching transfer,” Carbon, Vol. 197, pp. 218-225, 2022.

[13] Q. Ren^, Y. Zhang¹, S. Ma, X. Wang, K-C Chang, Y. Zhang, F. Yin*, Z. Li*, M. Zhang*, “Low-temperature supercritical activation enables high-performance detection of cell-free DNA by all-carbon-nanotube transistor,” Carbon, Vol. 196, No. 30, pp. 120-127, 2022.

[14] W. Huang^, Y. Wang, Y. Zhang, J. Zhu, D. Liu, J. Wang, L. Fan, R. Qiu, M. Zhang*, “Intrinsically stretchable carbon nanotube synaptic transistors with associative learning ability and mechanical deformation response,” Carbon, Vol.189, pp. 386-394, 2022.

[15] J. Wang^, J. Wang, J. Zhang, W. Huang, X. Wang, M. Zhang*, “Ultralow-power synaptic transistors based on Ta₂O₅/Al₂O₃ bilayer dielectric for algebraic arithmetic,” Advanced Electronic Materials, Vol. 8, No. 5, P. 2100922, 2022.

[16] J. Zhang^, M. Zhang*, K-C Chang, Z. Rong, Y. Zhang, S. Zhang, and M. Chan, “Analysis of carrier behavior for amorphous indium gallium zinc oxide after supercritical carbon dioxide treatment,” Advanced Materials Interfaces, Vol. 9, No. 14, P. 2102349, 2022.

[17] Y. Zhang^, Q. Huang, W. Huang, and M. Zhang*, “Ultra-flexible high-k transparent integratable fully-carbon-based capacitor arrays for sharp-switching transistors,” Carbon, Vol. 182, pp. 117-123, 2021.

[18] X. Wang^, K.-C. Chang, Z. Zhang, Q. Liu, L. Li, S. Ma, and M. Zhang*, “Performance enhancement and mechanism exploration of all-carbon-nanotube memory with hydroxylation and dehydration through supercritical carbon dioxide,” Carbon, Vol. 173, pp. 97-104, 2021.

[19] J. Zhang^, W. Huang, K.-C. Chang, Y. Shi, C. Zhao, X. Wang, H. Meng, S. Zhang, and M. Zhang*, “Performance enhancement and bending restoration for flexible amorphous indium gallium zinc oxide thin-film transistors by low-temperature supercritical dehydration treatment,” ACS Applied Materials & Interfaces, Vol. 13, No. 7, pp. 8584-8594, 2021.

[20] Y. Wang^, W. Huang, L. Fan, Z. Zhang, Q. Huang, J. Wang, Y. Zhang, and M. Zhang*, “Ultralow-power flexible transparent carbon nanotube synaptic transistors for emotional memory,” Nanoscale, Vol. 13, No. 26, pp. 11360-11369, 2021. (Cover Paper）

[21] L. Fan^, Q. Wang, Q. Huang, W. Huang, D. Liu, S. Ma, M. Zhang*, “Stretchable carbon nanotube thin-film transistor arrays realized by a universal transferable-band-aid method,” IEEE Transactions on Electron Devices, Vol. 68, No. 11, pp. 5879 - 5885, 2021.

[22] J. Wen^, C. Li, J. An, Z. Peng, H. Lin, M. Zhang*, and S. Zhang, “High-speed low-power rail-to-rail buffer using dynamic-current feedback for OLED source driver applications,” Analog Integrated Circuits and Signal Processing, Vol.110, pp. 115-125, 2021.

[23] J. Zhu^, C. Zhou, M. Zhang*, “Recent progress in flexible tactile sensor systems: from design to application,” Soft Science, pp.1-3, 2021.

[24] W. Huang^, H. Jiao, Q. Huang, J. Zhang, and M. Zhang*, “Ultra-high drivability, high-mobility, low-voltage and high-integration intrinsically stretchable transistors,” Nanoscale, Vol. 12, No. 46, pp. 23546-23555, 2020. (Cover Paper)

[25] Z. Zhang^, C. Du, H. Jiao, and M. Zhang*, “Polyvinyl alcohol/SiO₂ hybrid dielectric for transparent flexible/stretchable all-carbon-nanotube thin-film-transistor integration,” Advanced Electronic Materials, Vol. 6, No. 5, P. 1901133, 2020. (Cover Paper)

[26] W. Li*, Y. Gao¹^, J. Zhang, X. Wang, F. Yin*, Z. Li, and M. Zhang*, “Universal DNA detection realized by peptide based carbon nanotube biosensors,” Nanoscale Advances, Vol. 2, No. 2, pp. 717-723, 2020.

[27] C. Xie^, M. Zhang*, W. Du, C. Zhou, Y. Xiao, S. Zhang, and M. Chan, “Sensing-range-tunable pressure sensors realized by self-patterned-spacer design and vertical CNT arrays embedded in PDMS,” RSC Advances, Vol. 10, No. 55, pp. 33558-33565, 2020.

[28] H. Jiao^, M. Zhang*, C. Du, Z. Zhang, W. Huang, and Q. Huang, “Intrinsically stretchable all-carbon-nanotube transistors with styrene–ethylene–butylene–styrene as gate dielectrics integrated by photolithography-based process,” RSC Advances, Vol. 10, No. 14, pp. 8080-8086, 2020.

[29] C. Luo^, S. Long, G. Liu, Cooper, M. Zhang*, and F. Ai*, “Optimized optical design of thin-film transistor arrays for high transmittance and excellent chromaticity,” Frontiers of Materials Science, Vol. 14, No. 1, pp. 89-95, 2020. (The first author is my postdoctor)

[30] B. Zha^, M. Tang, J. Li, H. Chen, and M. Zhang*, “Effect of organic nano-pigments on contrast ratio of color filters,” Chinese Journal of Liquid Crystals and Displays, Vol. 35, No. 1, pp. 26-30, 2020. (The first author is my postdoctor)

[31] C. Du^, M. Zhang*, Q. Huang, S. Zhang, and Y. Chai, “Ultralow-voltage all-carbon low-dimensional-material flexible transistors integrated by room-temperature photolithography incorporated filtration,” Nanoscale, Vol. 11, No. 32, pp. 15029-15036, 2019. （Cover Paper）

[32] J. Zhang^, M. Zhang*, C. Du, S. Zhang, Z. Liao, Z. Rong, and L. Zhang, “Design and mechanism of embedding specific carbon nanotubes in sputtered sandwiched InGaZnO thin-film transistors,” IEEE Electron Device Letters, Vol. 40, No. 3, pp. 407-410, 2019.

[33] Z. Zhang^, M. Zhang*, C. Du, L. Li, and K.-C. Chang, “Improving performance of all-carbon-nanotube thin-film transistors by low temperature supercritical CO₂ fluid activation,” IEEE Electron Device Letters, Vol. 40, No. 6, pp. 921-924, 2019.

[34] B. Zha^, J. Li, J. Wu, X. Miao*, and M. Zhang*, “Cooperation and competition of hydrogen and halogen bonds in 2D self-assembled nanostructures based on bromine substituted coumarins,” New Journal of Chemistry, Vol. 43, No. 44, pp. 17182-17187, 2019. (The first author is my postdoctor)

[35] Q. Wang^, M. Zhang*, Q. Huang, Z. Liao, and C. Du, “Realizing controllable carbon nanotube arrays for soft devices by asymmetric Langmuir–Blodgett and hydrophilization process,” IEEE Transactions on Nanotechnology, Vol. 18, pp. 1144-1147, 2019.

[36] C. Luo^, G. Liu, and M. Zhang*, “Electric-field-induced microstructure modulation of carbon nanotubes for high-performance supercapacitors,” Frontiers of Materials Science, Vol. 13, No. 3, pp. 270-276, 2019. (The first author is my postdoctor)

[37] S. Zhang^, L. Wen, H. Wang, K. Zhu, and M. Zhang*, “Vertical CNT–Ecoflex nanofins for highly linear broad-range-detection wearable strain sensors,” Journal of Materials Chemistry C, Vol. 6, No. 19, pp. 5132-5139, 2018. (Cover Paper）

[38] H. Lin^, W. C. Chan, W. K. Lee, Z. Chen, M. Chan, and M. Zhang*, “High-current drivability Fibonacci charge pump with connect–point–shift enhancement,” IEEE Transactions on Very Large Scale Integration (T-VLSI) Systems, Vol. 25, No. 7, pp. 2164-2173, 2017.

[39] K. Zhu^, L. Wen, and M. Zhang*, “A carbon nanotube electrode a-IGZO-TFT,” IEEE Journal of the Electron Devices Society, Vol. 5, No. 5, pp. 411-415, 2017.

[40] H. Lin^, H. Cao, Z. Chen, W. C. Chan, W. K. Lee, and M. Zhang*, “Leakage current elimination for Dickson charge pump with a linear regulator,” Microelectronics Journal, Vol. 64, pp. 29-34, 2017.

[41] F. Yuan, Y. Deng^¹, W. Zhou*, M. Zhang*, and Z. Li*, “A simple and novel method for the quantitative detection of 5-hydroxymethylcytosine using carbon nanotube field-effect transistors,” Nano Research, Vol. 9, No. 6, pp. 1701-1708, 2016.

[42] H. Wang^, M. Shi, K. Zhu, Z. Su, X. Cheng, Y. Song, X. Chen, Z. Liao, M. Zhang*, and H. Zhang*, “High performance triboelectric nanogenerators with aligned carbon nanotubes,” Nanoscale, Vol. 8, No. 43, pp. 18489-18494, 2016.

[43] H. Lin^, W. C. Chan, W. K. Lee, Z. Chen, M. Chan, and M. Zhang*, “A high conversion ratio component-efficient charge pump for display drivers,” Journal of Display Technology, Vol. 12, No. 10, pp. 1057-1063, 2016.

[44] Y. Deng^, M. Zhang*, F. Yuan, Z. Li*, and W. Zhou*, “Uniform DNA biosensors based on threshold voltage of carbon nanotube thin-film transistors,” Nano, Vol. 11, No. 5, P. 1650060, 2016.

[45] H. Lin^, C. Chan Wing, K. Lee Wai, Z. Chen, and M. Zhang*, “Dickson charge pump with gate drive enhancement and area saving,” Journal of Power Electronics, Vol. 16, No. 3, pp. 1209-1217, 2016.

[46] H. Lin^, Z. Chen, W. Chan, W. Lee, and M. Zhang*, “Leakage current improvement for a voltage doubler charge pump,” Journal of Low Power Electronics, Vol. 12, No. 3, pp. 227-233, 2016.

[47] Y. Wu^, X. Lin, and M. Zhang*, “Carbon nanotubes for thin film transistor: fabrication, properties, and applications,” Journal of Nano materials, Vol. 2013, P. 627215, 2013.

[48] M. Zhang*, P. C. H. Chan, Y. Chai, Q. Liang, and Z. K. Tang, “Novel local silicon-gate carbon nanotube transistors combining silicon-on-insulator technology for integration,” IEEE Transactions on Nanotechnology, Vol. 8, No. 2, pp. 260-268, 2009.

[49] M. Zhang*, X. Huo, P. C. H. Chan, Q. Liang, and Z. K. Tang, “Radio-frequency transmission properties of carbon nanotubes in a field-effect transistor configuration,” IEEE Electron Device Letters, Vol. 27, No. 8, pp. 668-670, 2006.

[50] M. Zhang*, P. C. H. Chan, Y. Chai, Q. Liang, and Z. Tang, “Local silicon-gate carbon nanotube field effect transistors using silicon-on-insulator technology,” Applied Physics Letters, Vol. 89, No. 2, P. 023116, 2006.

       [51] M. Zhang*, X. Huo, P. C. H. Chan, Q. Liang, and Z. Tang, “Radio-frequency characterization for the single-walled carbon nanotubes,” Applied Physics Letters, Vol. 88, No. 16, P. 163109, 2006.

SELECTED CONFERENCE PUBLICATIONS

[1] T. Zhu¹, W. Wang¹, J. Zhu, and M. Zhang*, “An Intrinsically Flexible All-carbon Differential Amplifier with High Gain and Bandwidth,” International Flexible Electronics Technology Conference (IFETC), California, USA, August 13-16, 2023.

[2] Q. Ren^, S. Ma, X. Wang, Y. Zhang and M. Zhang*, “Mechanism exploration of enhanced biosensing performance for all-carbon-nanotube thin-film transistors,” IEEE Nanotechnology Materials and Devices Conference, Virtual, Online, November 18-20, 2022.

[3] R. Qiu^, Q. Ren, Q. Liu, L. Lu and M. Zhang*, “An etching-free method for patterning carbon nanotube films enabled by universal wettability modulations,” IEEE Nanotechnology Materials and Devices Conference, Virtual, Online, November 18-20, 2022.

[4] Q. Ren^, S. Ma^ and M. Zhang*, “Tetrahedral DNA nanostructure based all-carbon-nanotube transistor biosensor for high-performance detection of circulating tumor,” iCANX-Summit, Wuhan, China, April 26-29, 2022. (Outstanding Student Paper: Second Prize)

[5] D. Liu^, W. Huang, Q. Ren, M. Zhang*, “A photoinduced electrostatic doping effect in carbon nanotube field-effect transistors,” IEEE International Conference on Nanotechnology (IEEE-NANO), Virtual, Online, July 28-30, 2021.

[6] Y. Huang^, S. Ma, J. Zhang, C. Xie, and M. Zhang*, “Modulating the electrical transport characteristics of a metal-semiconductor-metal structure by local strain gradient,” IEEE International Conference on Nano/Micro Engineered & Molecular Systems (NEMS), Xiamen, China, April 25-29, 2021.

[7] C. Li^, D. Zhang, W. Zeng, H. Lin, and M. Zhang*, “A high current-drive, step-up capacitive power converter for display driver,” SID Symposium Digest of Technical Papers, Virtual, Online, August 3-7, 2020.

[8] Y. Sun^*, J. Fan, Y. Yin, M. Liu, P. Jiang, L. Zhang, B. Jiang, C. Yuan, M. Zhang*, S.-j Chen, C.-Y Lee, and X. Zhang, “High transparent, ultra‐thin flexible, full color Mini‐LED display with IGZO TFT substrate,” SID Symposium Digest of Technical Papers, Virtual, Online, August 3-7, 2020. (The first author is my postdoctor)

[9] Y. Zhang^*, W. Cao, Q. Zhang, Y. Zhang, Z. Huang, Y. Lin, J. Xiao, and M. Zhang*, “Curing mechanism and optimal solution for interior disclination in ultrahigh-definition 2-domain VA LCD,” SID Symposium Digest of Technical Papers, Virtual, Online, August 3-7, 2020. (The first author is my postdoctor)

[10] Y. Zhang^*, W. Cao, Q. Zhang, Y. Zhang, Y. Lin, J. Xiao, and M. Zhang*, “Novel pixel design for transmittance and picture quality improvement,” SID Symposium Digest of Technical Papers, Virtual, Online, August 3-7, 2020. (The first author is my postdoctor)

[11] Y. Wang^, Y. Gao, W. Li, M. Zhang*, J. Zhang, Q. Wang, Z. Zhang, and Z. Li*, “Applying viscous shear stress to align single-walled carbon nanotubes,” IEEE Electron Devices Technology and Manufacturing (EDTM) Conference, Penang, Malaysia, April 6-21, 2020.

[12] Y. Sun^*, J. Fan, B. He, M. Zhang*, S. Chen, X. Zhang*, C. Lee, and Q. Fang, “A full-color Micro LEDs display based on IGZO TFT,” IEEE International Conference on Electronics Technology (ICET), Chengdu, China, May 8-12, 2020.

[13] N. Li^, Z. Rong, L. Zhang*, and M. Zhang*, “A dual-gate IGZO source-gated transistor based on field modulation by TCAD simulation,” IEEE International Conference on Solid-State & Integrated Circuit Technology (ICSICT), Kunming, China, November 3-6, 2020.

[14] Q. Huang^, Q. Wang, Z. Liao, C. Du, and M. Zhang*, “Integration and characterization of transparent thin film transistors with carbon nanotubes as aligned channel and electrodes,” IEEE International Conference on Nanotechnology (IEEE-NANO), Macao, China, July 22-26, 2019.

[15] D. Zhang^, W. Zeng, H. Lin, J. Wen, C. Li, and M. Zhang*, “Efficiency enhancement by non-overlapping time design and adaptive ratio control for charge pump of display drivers,” SID Symposium Digest of Technical Papers, Virtual, Online, May 12-17, 2019.

[16] W. Zeng^, C. Li, D. Zhang, J. Huang, J. Wen, B. Liu, H. Lin, S. Zhang, and M. Zhang*, “A novel pixel circuit with threshold voltage variation compensation in three-dimensional AMOLED on Silicon Microdisplay,” SID Symposium Digest of Technical Papers, Virtual, Online, May 12-17, 2019.

[17] Y. Zhang^*, X. Li, Y. Zhang, W. Cao, Q. Zhang, Y. Lin, J. He, C.-Y. Chiu, R. Lin, and M. Zhang*, “Pixel design solutions for transmittance improvement in 8K VA LCD,” SID Symposium Digest of Technical Papers, Virtual, Online, May 12-17, 2019. (The first author is my postdoctor)

[18] Q. Wang^, Q. Huang, Z. Liao, C. Du, and M. Zhang*, “Asymmetric Langmuir-Blodgett and hydrophilization process to realize density-controllable carbon nanotube array on flexible and stretchable substrates,” IEEE International Conference on Nano/Micro Engineered and Molecular Systems (NEMS), Bangkok, Thailand, April 11-14, 2019

[19] J. Wen^, H. M. Lam, C. Li, D. Zhang, W. Zeng, H. Lin, and M. Zhang*, “Design of a peripheral-circuit-compensation adjustable-gamma-voltage driving chip for OLED-on-silicon Microdisplay,” IEEE International Conference on Electron Devices and Solid-State Circuits (EDSSC), Xi'an, China, June 12-14, 2019.

[20] D. Ding^, H. Lin, B. Liu, and M. Zhang*, “A step-up charge pump with high integration and full-coverage voltage conversion ratio,” IEEE International Symposium on Circuits and Systems (ISCAS), Florence, Italy, May 27-30, 2018.

[21] J. Zhang^, Z. Liao, Y. Gao, and M. Zhang*, “Embedding Langmuir-Blodgett carbon nanotube array to enhance performance of amorphous InGaZnO thin film transistor,” IEEE International Conference on Nanotechnology (IEEE-NANO), Cork, Ireland, July 23-27, 2018.

[22] H. Lin^, D. Ding, B. Liu, D. Zhang, J. Wen, and M. Zhang*, “A multi‐phase, high‐current‐drivability charge pump in display driver ICs,” SID Symposium Digest of Technical Papers, Los Angeles, CA, May 21-25, 2018.

[23] J. Wen^, B. Liu, T. Zhou, H. Lin, and M. Zhang*, “High-slew-rate low-static-power dynamic-bias rail-to-rail output buffer for OLED-on-silicon VR Microdisplay,” SID Symposium Digest of Technical Papers, Los Angeles, CA, May 21-25, 2018.

[24] B. Liu^, H. Lin, D. Ding, D. Zhang, and M. Zhang*, “An algorithm for full-coverage voltage-conversion-ratio Fibonacci-like charge pump,” IEEE International Conference on Electron Devices and Solid State Circuits (EDSSC), Shenzhen, China, June 6-8, 2018.

[25] D. Zhang^, B. Liu, H. Lin, D. Ding, and M. Zhang*, “A high-efficient, multi-phase charge pump scheme,” IEEE International Conference on Electron Devices and Solid State Circuits (EDSSC), Shenzhen, China, June 6-8, 2018.

[26] D. Zhang^, R. Zhang, H. Lin, Q. Wang, and M. Zhang*, “An on-chip oscillator with comparator offset cancellation,” IEEE International Conference on Electron Devices and Solid State Circuits (EDSSC), Shenzhen, China, June 6-8, 2018.

[27]S. Zhang^, H. Wang, L. Wen, K. Zhu, Z. Liao, Y. Deng, and M. Zhang*, “Reinforced standing multi-walled carbon nanotube film for stretchable strain sensor,” IEEE International Conference on Nanotechnology (IEEE-NANO), Pittsburgh, PA, July 25-28, 2017.

[28] C. Du^, Y. Deng, K. Zhu, Y. Gao, and M. Zhang*, “Transparent all-carbon-nanotube thin-film transistors,” IEEE International Conference on Nanotechnology (IEEE-NANO), Pittsburgh, PA, July 25-28, 2017.

[29] Z. Liao^, Y. Gao, Y. Deng, C. Du, S. Zhang, Q. Lin, and M. Zhang*, “On-current tunable carbon nanotube thin-film transistor by SiO₂ passivation layer,” IEEE International Conference on Nanotechnology (IEEE-NANO), Pittsburgh, PA, July 25-28, 2017.

[30] Y. Gao^, Y. Deng, Z. Liao, and M. Zhang*, “Aligned carbon nanotube field effect transistors by repeated compression-expansion cycles in Langmuir-Blodgett,” IEEE International Conference on Nanotechnology (IEEE-NANO), Pittsburgh, PA, July 25-28, 2017.

[31] B. Liu^, D. Ding, T. Zhou, and M. Zhang*, “A novel pixel circuit providing expanded input voltage range for OLEDoS Microdisplays,” SID Symposium Digest of Technical Papers, Los Angeles, CA, USA, May 23-25, 2017.

[32] D. Ding^, B. Liu, T. Zhou, H. Lin, and M. Zhang*, “A Fibonacci-like charge pump and its current drive capacity enhancement for display driver ICs,” SID Symposium Digest of Technical Papers, Los Angeles, CA, USA, May 23-25, 2017.

[33] X. Cheng, L. Miao, H. Chen, Y. Song, Z. Su, X. Chen, H. Wang, M. Zhang*, and H. Zhang*, “Triboelectrification based active sensor for liquid flow and bubble detecting,” IEEE International Conference on Micro Electro Mechanical Systems (MEMS), Las Vegas, NV, January 22-26, 2017.

[34] L. Wen^ and M. Zhang*, “A theoretical and numerical study on percolation mechanism of carbon nanotube network,” IEEE International Conference on Nanotechnology (IEEE-NANO), Sendai Japan, August 22-25, 2016.

[35] Y. Deng^, M. Chan, and M. Zhang*, “Fully transparent solution-processed carbon nanotube thin film transistors on a flexible substrate,” IEEE International Conference on Nanotechnology (IEEE-NANO), Sendai Japan, August 22-25, 2016.

[36] T. Zhou^, C. Leng, H.-M. Lam, H. Lin, S. Zhang, and M. Zhang*, “An area-efficient segmented R-DAC realized by low-voltage transistors for AMOLED driver ICs,” SID Symposium Digest of Technical Papers, San Francisco, CA, USA, May 22-27, 2016.

[37] C. Chen^, Y. Deng, P. He, and M. Zhang*, “Rapid thermal annealing for carbon nanotube thin film transistors by a double-thermal-region furnace,” IEEE Annual International Conference on Nano/Micro Engineered and Molecular Systems (NEMS), Sendai, Japan, April 17-20, 2016.

[38] H. Wang^, M. Shi, K. Zhu, Z. Su, M. Zhang*, and H. Zhang, “Fabrication of stretchable and flexible vertically aligned carbon nanotube film,” IEEE Annual International Conference on Nano/Micro Engineered and Molecular Systems (NEMS), Sendai, Japan, April 17-20, 2016.

[39] P. He^, Y. Deng, C. Chen, and M. Zhang*, “A novel thin-film transistor using carbon nanotubes as both channel and electrodes,” IEEE International Conference on Electron Devices and Solid-State Circuits (EDSSC), Hong Kong, China, August 3-5, 2016.

[40] Z. Liao^, H. Lin, B. Liu, and M. Zhang*, “Mobility variation and threshold voltage shift immunized amorphous-indium-gallium-zinc-oxide pixel circuit,” IEEE International Conference on Electron Devices and Solid-State Circuits (EDSSC), Hong Kong, China, August 3-5, 2016.

[41] B. Liu^, S. Zhang, D. Ding, T. Zhou, and M. Zhang*, “A novel pixel circuit for 2826 ppi OLEDoS microdisplays based on PWM,” China FPD Conference, Hefei, China, September 22-24, 2016.

[42] K. Zhu^, Y. Wu, and M. Zhang*, “High-performance carbon nanotube/InGaZnO composite thin film transistors and concentration effect,” International Conference on Nanotechnology (IEEE-NANO), Rome, Italy, July 27-30, 2015.

[43] H. Lin^, M. Zhang*, W. C. Chan, and W. K. Lee, “A low-power regulator for display driver IC requiring a moderate current drivability,” IEEE International Conference on Electron Devices and Solid-State Circuits (EDSSC), Singapore, June 1-4, 2015.

[44] H. Lin^, M. Zhang*, W. C. Chan, and W. K. Lee, “A novel linear regulator in build-in capacitor Dickson charge pump applications with low output ripple,” IEEE International Conference on Electron Devices and Solid-State Circuits (EDSSC), Singapore, June 1-4, 2015.

[45] Y. Deng^, Y. Wu, and M. Zhang*, “Annealing temperature optimization for high-performance carbon nanotube thin film transistors,” IEEE International Conference on Electron Devices and Solid-State Circuits (EDSSC), Singapore, June 1-4, 2015.

[46] W. Jiang^, H. Lam, H. Shao, H. Lin, and M. Zhang*, “A distributive on-chip voltage regulation scheme for power supply in AMOLED driver ICs,” IEEE International Conference on ASIC (ASICON), Chengdu, China, November 3-6, 2015.

[47] Y. Wu^, M. Zhang*, and M. Chan, “Using 0-dimensional silica to control diameter and density of carbon nanotubes,” IEEE International Conference on Nanotechnology (IEEE-NANO), Toronto, ON, Canada, August 18-21, 2014.

[48] Y. Wu^, M. Zhang*, X. Xiao, and S. Zhang, “Indium gallium zinc oxide - carbon nanotube composite thin film transistor,” IEEE International Conference on Electron Devices and Solid-State Circuits (EDSSC), Chengdu, China, June 18-20, 2014.

[49] H. Lin^, M. Zhang*, W. C. Chan, W. K. Lee, and M. Chan, “A novel makowski charge pump and its optimization using lagrange theorem,” IEEE International Conference on Solid-State and Integrated Circuit Technology (ICSICT), Guiling, China, October 28-31, 2014.

[50] M. Zhang*, P. C. H. Chan, Y. Chai, and Z. Tang, “Applying SOI technology on carbon nanotube transistors,” IEEE international SOI Conference Proceedings, New York, USA, October 2-5, 2006.

[51] M. Zhang*, P. C. H. Chan, Q. Liang, and Z. Tang, “A novel local bottom-gate carbon nanotube field effect transistor on SOI,” IEEE international SOI Conference Proceeding I, Newport Beach, USA, September 29-Oct 2, 2003.

AUTHORIZED PATENTS

1.   张敏，黄巍宏，焦浩轩，黄秋月，张娇娜；一种可拉伸半导体器件的制备方法，2022-9-20，中国，ZL 202010991589.1；

2.   林兴武， 张盛东，张敏，焦海龙，黄杰，邱赫梓，李成林，文金元；一种反馈信号检测方法及像素外模拟域补偿显示系统，2022-6-17，中国，ZL 202011037598.3;

3.  林兴武， 张盛东，张敏，焦海龙，黄杰，邱赫梓，李成林，文金元；一种反馈信号检测方法及显示系统，2022-6-17，中国，ZL 202011037580.3；

4.   林兴武，张盛东，张敏，焦海龙，邱赫梓，李成林；一种像素单元及像素外模拟域补偿显示系统，2022-3-1，中国，ZL 202011495974.3；

5.   张敏，林和生，丁德东，刘宾杰；多相位不交叠时钟信号产生电路及相应的方法，2021-11-5，中国，ZL 201711237527.6；

6.   张敏，曾韦玲； 微显示像素装置、微显示装置及补偿方法，2021-03-19，中国，ZL 201910679321.1；

7.   张敏，刘宾杰，林和生，丁德东；一种比较装置以及包括该比较装置的线性稳压装置，2021-02-05，中国，ZL 201810115508.4；

8.   张敏，张硕，王焕；应力传感器及其制备的方法，2020-07-14，中国，ZL 201710337940.3；

9.   张敏，林和生，丁德东；电荷泵电路，2020-04-14，中国，ZL 201710916586.X ；

10. 张敏，林和生，刘宾杰，张硕；具有增强驱动能力的电荷泵电路，2019-12-03，中国，ZL 201711079617.7；

11. 张敏，周天宇；像素装置、驱动像素装置的方法和显示设备，2019-10-08，中国，ZL 201710388441.7；

12. 张敏，林和生；一种Fibonacci电荷泵，2019-02-0-26，中国，ZL 201610890464.3；

13. 张敏，吴玉翠；用于生长碳纳米管的方法，2018-08-28，中国，ZL 201510085610.0；

14. 林兴武，张盛东，焦海龙，张敏，文金元，白文龙，邱赫梓，李成林，像素阵列的补偿驱动方法、驱动装置以及显示设备，2021-10-22，中国，ZF 2020106093363；

15. 张盛东，邱赫梓，廖聪维，郭凡，林兴武，鲁文高，张敏；加法器单元以及显示设备，2020-11-27，中国，ZL 201910070697.2；

16. 林兴武，张盛东，张敏，冷传利，王翠翠，胡治晋，孟雪，周天宇，杨方方；显示装置及其显示驱动器，2018-07-06，中国，ZL 201610165199.2；

17. 林兴武，张盛东，冷传利，王翠翠，孟雪，张敏；一种具有反馈通道的显示系统，2018-03-20，中国，ZL 201510618674.2；

18. 林兴武，张盛东，冷传利，王翠翠，孟雪，张敏；一种像素矩阵的外围补偿系统、方法和显示系统，2017-11-28，中国，ZL 2015104080616.

1. 背景：具备微电子、半导体器件、物理、集成电路设计等基础；

2. 具有较强的实验能力、器件机理、理论及建模、逻辑思维和表达能力，对所从事研究的领域具有兴趣和好奇心；

3. 英语阅读、写作能力强；

4. Attitude=100. (Result-orientated, Self- motivated, Enjoying research and life).