马汉彬研究员
研究方向：
电子邮件：mahb@sibet.ac.cn
电话：(0512) **
通讯地址：苏州高新区科灵路88号







简历： 2008年本科毕业于吉林大学电子科学与工程学院，同年加入中科院苏州纳米技术与纳米仿生研究所系统集成部，从事CMOS传感器芯片开发工作。2009年前往英国伦敦大学学院攻读纳米技术硕士，2010年进入剑桥大学电子工程系攻读博士学位。2013年，获得了由中国国家留学基金委颁发的国家优秀自费留学生奖。2014年4月获得博士学位，继续留任研究助理，进行研发及学生培养等工作。后受到艾萨克牛顿基金会支持，以牛顿研究员的身份在剑桥大学进行阻抗式低成本生物传感器及探测系统研发工作。2018年初，加入中国科学院苏州生物医学工程技术研究所，所微纳加工平台负责人。发表SCI期刊论文20余篇，申请专利30余项，其中2项英国专利、4项中国发明专利获得授权。

获奖及荣誉：
社会任职：
研究方向： 　　　　基于先进半导体制造工艺、薄膜电子技术的阵列式生物芯片、生物传感器系统开发。　　
　　·阵列式电化学生物检测平台
　　通过类似平板显示像素的驱动电路，配合基于薄膜晶体管的放大器像素电路，有能力实现大面积、高通量的阵列式阻抗生物传感器的制备。
　　·数字微流控芯片及平台
　　利用电润湿数字微流控技术，实现片上全流程生物反应。利用薄膜晶体管像素开关阵列，实现在大规模阵列上的高通量生物样本精准操控。
　　

承担项目情况：
代表论著： --2020--
[24] G Yao, H Ma*, S Sambandan, J Robertson and A Nathan, “Indium silicon oxide TFT fully photolithographically processed for circuit integration”, IEEE Journal of the Electron Devices Society, online
[23] W Hou, S Hu, K-T Yong, J Zhang* and H Ma*, “Cigarette smoke-induced malignant transformation via STAT3 signalling in pulmonary epithelial cells in a lung-on-a-chip model”, Bio-Design and Manufacturing, 2020, online
[22] S Hu, B Zhang, S Zeng, L Liu, K-T Yong, H Ma* and Tang Y, “Microfluidic Chips Enabled One-step Synthetization of Biofunctionalized CuInS₂/ZnS Quantum Dots”, Lab on a chip, 2020, 20, 3001
[21] C Zhang, Y Su, S Hu, K Jin, Y Jie, W Li, A Nathan and H Ma*. “An impedance sensing platform for monitoring heterogeneous connectivity and diagnostics in lab-on-a-chip systems”, ACS omega 5 (10), 5098-5104
[20] H Ma*, S Hu, Y Jie, K Jin and Y Su*. “A floating top-electrode electrowetting-on-dielectric system”, RSC Advances 10 (9), 4899-4906
[19] K Jin, P Zhao, W Fang, Y Zhai, S Hu, H Ma and J Li. “An Impedance Sensor in Detection of Immunoglobulin G with Interdigitated Electrodes on Flexible Substrate”. Applied Sciences 10 (11), 4012
--2019--
[18] K Jin, S Hu, Y Su, C Yang, J Li* and H Ma*. “Disposable impedance-based immunosensor array with direct-laser writing platform”, Analytica Chimica Acta 1067, 48-55
[17] S Hu, Y Ren, Y Wang, J Li, J Qu, L Liu*, H Ma* and Y Tang. “Surface plasmon resonance enhancement of photoluminescence intensity and bioimaging application of gold nanorod@CdSe/ZnS quantum dots” Beilstein Journal of Nanotechnology, 2019, 10, 22-31
[16] C Jiang, H W Choi, X Cheng, H Ma, D G.Hasko and A Nathan*. “Printed subthreshold organic transistors operating at high gain and ultralow power” Science, 2019, 363(6248), pp 719-723
[15] W Hou, S Hu, C Li, H Ma, Q Wang, G Meng, T Guo, J Zhang. “Cigarette smoke induced lung barrier dysfunction, EMT, and tissue remodeling: a possible link between COPD and lung cancer”. BioMed Research International 2019
--2019前--
[14] C. Day, S. Sopstad, H. Ma, C. Jiang, A. Nathan, S.R. Elliott, F.E. Karet Frankl and T. Hutter*. “Impedance-based sensor for potassium ions” Analytica Chimica Acta, 2018, 1034, pp 39-45
[13] Y Su, H Li, H Ma, H Wang, J Robertson, A Nathan. “Dye-Assisted Transformation of Cu2O Nanocrystals to Amorphous CuxO Nanoflakes for Enhanced Photocatalytic Performance”. ACS omega 3 (2), 1939-1945
[12] Z Guo, L Zhou, Y Tang, L Li, Z Zhang, H Yang, H Ma, A Nathan, D Zhao. “Surface/Interface Carrier-Transport Modulation for Constructing Photon-Alternative Ultraviolet Detectors Based on Self-Bending-Assembled ZnO Nanowires” ACS Applied Materials & Interfaces 9 (36), 31042-31053
[11] C Jiang, H Ma, D G.Hasko, X Guo and A Nathan. “A Lewis-Acid Monopolar Gate Dielectric for All-Inkjet-Printed Highly Bias-Stress Stable Organic Transistors.” Advanced Electronic Materials, 2017,3,**
[10] Y Su, H Li, H Ma, J Robertson, A Nathan*. "Controlling surface termination and facet orientation in Cu₂O nanoparticles for high photocatalytic activity: a combined experimental and density functional theory study." ACS Applied Materials & Interfaces, 2017, 9(9), pp 8100-8106
[9] S Gao, X Wu, H Ma, J Robertson, A Nathan. “Ultrathin multifunctional graphene-PVDF layers for multidimensional touch interactivity for flexible displays” ACS Applied Materials & Interfaces 9 (22), 18410-18416
[8] H Ma, Y Su, C Jiang and A Nathan*. "Inkjet-printed Ag electrodes on paper for high sensitivity impedance measurements." RSCAdvances 6 (87), 84547-84552
[7] L Feng, C Jiang, H Ma, X Guo and A Nathan*. "All ink-jet printed low voltage organic field-effect transistors on flexible substrate." Organic Electronics 38, 186-192
[6] C Jiang, H Ma, D G. Hasko, and A Nathan*. "Influence of polarization on contact angle saturation during electrowetting."Applied Physics Letters109, no. 21 (2016): 211601
[5] C Tsangarides, H Ma and A Nathan*. "ZnO nanowire array growth on precisely controlled patterns of inkjet-printed zinc acetate at low-temperatures." Nanoscale 8 (22), 11760-11765
[4] Y Su, A Nathan, H Ma, H Wang. “Precise control of Cu₂O nanostructures and LED-assisted photocatalysis” RSC Advances 6 (81), 78181-78186
[3] H Ma, J Li, X Cheng and A Nathan*. "Heterogeneously integrated impedance measuring system with disposable thin-film electrodes."Sensors and Actuators B: Chemical211 (2015): 77-82
[2] H Ma, Y Su and A Nathan*. "Cell constant studies of bipolar and tetrapolar electrode systems for impedance measurement." Sensors and Actuators B: Chemical (2015): 1264-1270
[1] H Ma, R Wallbank, R Chaji, J Li, Y Suzuki, C Jiggins and A Nathan*. "An impedance-based integrated biosensor for suspended DNA characterization." Scientific Report, Nature Publishing Group, 3:2730