一、个人简介

王楠，大连理工大学集成电路学院副教授，博士生导师，现担任半导体传感器与集成微系统研究中心副主任，集成电路学院科研秘书。先后从新加坡南洋理工大学获得硕士学位和博士学位。2016年，作为访问学者受邀在麻省理工学院机械工程系访学。2017年，在新加坡-麻省理工学院研究与技术联盟中心开始了博士后的研究工作。随后，在新加坡科技设计大学担任博士后研究员。相关科研成果已发表在国际高水平学术期刊  (Journal of Hazardous Materials、Sensors and Actuators B: Chemical、ACS Applied Materials & Interfaces、Microchimica Acta、Microchemical Journal等) 以及具有国际影响力的学术会议上 (IEEE TRANSDUCERS、MicroTAS、APCOT、IEEE MEMS、BIOSENSORS、IEEE SENSORS、IEEE INEC、IMCS、ICICM等)。长期担任Chemical Engineering Journal、Sensors and Actuators B: Chemical、ACS Sensors、Analytical Chemistry等国际学术期刊的审稿人，与国内外科研学者建立了广泛的交流与合作。主要科研方向包括(1) 基于二维材料的电化学传感器；(2) 基于半导体材料的气体传感器；(3) 基于功能性材料的生物传感器。

二、荣誉及获奖

2024. 10        在第九届集成电路与微系统国际会议上担任技术委员会成员

2024. 06        荣获2024年度大连理工大学优秀硕士学位论文指导教师

2024. 06        荣获2024年度大连理工大学优秀本科毕业论文指导教师

2024. 01        荣获大连理工大学2022-2023学年优秀专业班主任

2023. 08        荣获第十九届化学传感器国际会议最佳口头报告奖

2023. 06        荣获2023年度大连理工大学优秀本科毕业论文指导教师

2022. 12        荣获大连理工大学开发区校区第二届“线上教学创新竞赛”二等奖

2022. 09        荣获大连理工大学2021年度校教学质量优良奖

2021. 12        荣获大连理工大学青年教师讲课竞赛三等奖

2020. 01        被推荐参加2020年全球青年科学家峰会 (新加坡)

2018. 01        在第八届IEEE纳米电子学国际会议上担任分会主席

2015. 11        被推荐参加第十届亚洲与大洋洲顶尖大学工学院联盟年会

2013. 01        荣获新加坡-麻省理工学院研究与技术联盟中心全额博士奖学金

2012. 12        荣获南洋理工大学“杰出表现”荣誉证书

三、代表性学术成果

[1] Wang N., Kanhere E., Miao J.M., Triantafyllou M.S. Miniaturized chemical sensor with bio-inspired micropillar working electrode array for lead detection. Sensors and Actuators B: Chemical, 2016, 233, 249-256.

[2] Kanhere E., Wang N., Kottapalli A.G.P., Asadnia M., Subramaniam V., Miao J.M., Triantafyllou M.S. Crocodile-inspired dome-shaped pressure receptors for passive hydrodynamic sensing. Bioinspiration & Biomimetics, 2016, 11, 056007.

[3] Wang N. Biological olfaction inspired chemical sensors. In Kottapalli A.G.P., Asadnia M., Miao J.M., Triantafyllou M.S. (Eds.), Biomimetic Microsensors Inspired by Marine Life. Springer, Cham, 2017, 23-51.

[4] Wang N., Kanhere E., Kottapalli A.G.P., Miao J.M., Triantafyllou M.S. Flexible liquid crystal polymer-based electrochemical sensor for in-situ detection of zinc(II) in seawater. Microchimica Acta, 2017, 184, 3007-3015.

[5] Kanhere E., Wang N., Kottapalli A.G.P., Miao J.M., Triantafyllou M.S. Hemispherical array of sensors with contractively wrapped polymer petals for flow sensing. Smart Materials and Structures, 2017, 26, 115008.

[6] Wang N., Kanhere E., Miao J.M., Triantafyllou M.S. Nanoparticles-modified chemical sensor fabricated on a flexible polymer substrate for cadmium(Ⅱ) detection. Polymers, 2018, 10, 694.

[7] Wang N., Kanhere E., Tao K., Hu L.X., Wu J., Miao J.M., Triantafyllou M.S. Investigation of a thin-film quasi-reference electrode fabricated by combined sputtering-evaporation approach. Electroanalysis, 2019, 31, 560-566.

[8] Wu J., Sun Y.M, Wu Z.X., Li X., Wang N., Tao K., Wang G.P. Carbon nanocoil-based fast-response and flexible humidity sensor for multifunctional applications. ACS Applied Materials & Interfaces, 2019, 11, 4242-4251.

[9] Wang N., Miao J.M., Triantafyllou M.S. Chemical sensor for heavy metal detection. US Patent, 2020, 10690647.

[10] Tao K., Yi H.P., Yang Y., Chang H.L., Wu J., Tang L.H., Yang Z.S., Wang N., Hu L.X., Fu Y.Q., Miao J.M., Yuan W.Z. Origami-inspired electret-based triboelectric generator for biomechanical and ocean wave energy harvesting. Nano Energy, 2020, 67, 104197.

[11] Hao S., Zhong S., Ji X.L., Pang K.Y., Wang N., Li H.M., Jiang Y., Lim K.G., Chong T.C., Zhao R., Loke D.K. Activating silent synapses in sulfurized indium selenide for neuromorphic computing. ACS Applied Materials & Interfaces, 2021, 13, 60209–60215.

[12] Wang N.*, Bora M., Hao S.*, Tao K., Wu J., Hu L.X., Liao J.J., Lin S.W., Triantafyllou M.S., Li X.G. Hyaluronic acid methacrylate hydrogel-modified electrochemical device for adsorptive removal of lead(II). Biosensors-Basel, 2022, 12, 714.

[13] Li X.L., Sun S.P., Wang N., Huang B.Y.*, Li X.G. SnTe/SnSe heterojunction based ammonia sensors with excellent withstand to ambient humidities. Small, 2023, 2309831.

[14] Zhang S., Sun S.P., Huang B.Y., Wang N., Li X.G*. UV-enhanced formaldehyde sensor using hollow In2O3@TiO2 double-layer nanospheres at room temperature. ACS Applied Materials & Interfaces, 2023, 15, 4329-4342.

[15] Hao S.*, Han S.C., Zhang J.C., Li J.J., Wang N., Li X.G. Improving contacts and electrical performances of nanofilms of MoS2 transistors through ultrastrong vdW integration with Dirac semimetal PtTe2. ACS Applied Nano Materials, 2023, 6, 2285-2291.

[16] Wang N.*, Ma Y.T., Yu X.S., Tao H.J., Xu A.H., Huang B.Y., Hao S., Liao J.J., Lin S.W., Bian C., Li X.G. Ultrasensitive detection of thiamethoxam by an aptasensor modified with reduced graphene oxide and Au nanoparticles. Microchemical Journal, 2024, 207, 112169.

[17] Wang N.*, Li J.Q., Ma Y.T., Xu A.H., Tao H.J., Huang B.Y., Hao S., Liao J.J., Lin S.W., Tang Y.P., Hou Y., Bian C., Li X.G. Electrochemical detection of Pb(II) ions in aqueous solution by carbon nanospheres modified boron‑doped diamond electrode. Journal of Analysis and Testing, 2024, 8, 493-504.

[18] Xu A.H., Sun S.P., Li X.L., Wang N.*, Wang X.Y., Tao H.J., Ma Y.T., Zhang Z., Huang B.Y., Li X.G. Ultrasensitive ammonia sensor with excellent humidity resistance based on PANI/SnS2 heterojunction. Journal of Hazardous Materials, 2025, 487, 137181.

[19] Tao H.J., Wang N.*, Ma Y.T., Xu A.H., Huang B.Y., Li X.G. Rapid and portable detection of Pb(II) and Cd(II) ions using a screen-printed graphene electrode enhanced with alkalized MXene and gold nanoparticles. Journal of The Electrochemical Society, 2025, 172, 017504.

[20] Sun S.P., Li X.L., Sun Y.H., Wang N., Huang B.Y., Li X.G*. Fabrication of TeNT/TeO2 heterojunction based sensor for ultrasensitive detection of NO2. Journal of Hazardous Materials, 2025, 487, 137229.