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个人简介
侯丽珍,女,博士,教授,博士生导师。2001年6月硕士毕业于湖南师范大学物理系,之后留校任教。2008年1月获在湖南师范大学获理学博士学位。2012年至2018年期间,先后在中南大学和澳大利亚昆士兰大学从事博士后研究。主持包括国家自然基金面上基金和青年基金在内的多项研究课题,并作为第一/通讯作者在Carbon,Applied Physics Letters, Applied Surface Science和Friction等国际知名期刊上发表30多篇研究论文。与澳大利亚昆士兰大学采矿与机械工程学院的“纳米力学与纳米制造”研究团队、德国奥尔登堡大学的微机器人与控制工程系(AMiR)的“微纳机器人和微纳操纵”研究团队、中南大学物理学院的“纳米材料、纳米力学与纳米制造”研究团队建立有长期合作关系。所从事的研究课题涉及凝聚态物理、纳米力学和纳米制造等多个研究领域,主要的研究方向包括:(1)纳米材料与纳米结构的可控制备与机理研究、性能(力/光/电磁波吸收)表征与应用研究,(2)仿生表面材料的可控制备、性能表征和应用研究,(3)基于光学显微镜的新型微纳操纵技术的开发和应用研究。
Email: lizhenhou@hunnu.edu.cn
学术贡献
1.建立了碳包覆多元合金纳米颗粒的气相合成方法,实现了碳包覆多元合金纳米颗粒的低成本、大批量、可控合成,初步阐明了多种碳包覆多元合金纳米颗粒的磁性能和电磁波吸收性能的调控机理,为碳包覆FeCoNi基高熵合金纳米在电磁波吸波领域的实际应用奠定了基础。
2.创建了基于光学显微镜的微纳操纵技术,实现单个一维和二维纳米结构以及单个微米颗粒在大气环境下的可视化操纵,并将该技术用于单根一维纳米材料的力学性能、表面黏附和表面摩擦行为的定量表征,单个纳米片的表面黏附行为表征,以及微米颗粒的三维组装。该项研究为单个微纳结构/材料在大气环境下的可视化操纵提供了可能,通过可视化方式加深和改善了人们对纳米尺度下的界面摩擦和粘附行为的认识和理解,并对微纳器件的加工制造和组装,以及表界面材料的设计等方面具有重要的应用价值。
3.建立了可对单根纳米线在大气环境下的摩擦行为进行系统研究的可视化表征方法,阐明了接触表面的化学特性和原子台阶对纳米线摩擦行为的影响机制,并定量表征了环境湿度和界面滑移速率对纳米线摩擦行为的影响。该项研究结果不仅能改善人们对低维材料的界面摩擦行的认识和理解,而且对基于微纳纤维状结构的仿生表面材料的设计和应用具有重要的指导意义。
教学情况
本科生教学:力学;理论力学;普通物理;高等数学(三);概率论与数理统计;大学物理实验。
研究生教学:现代光学实验;胶体物理。
承担课题
1.主持国家自然科学基金面上项目:自支撑超薄膜与基底之间界面吸附能的定量测量和机理研究(No.12072111)项目起止年月:2021.01-2024.12
2.主持长沙市自然科学基金项目:自支撑超薄膜的表面黏附行为研究(No.kq2007002)项目起止年月:2020.05-2022.06
3.主持国家自然科学基金青年项目:纳米晶须与基底之间摩擦力的定量测量及其形成机理(No. 11502080)项目起止年月:2016.01-2018.12
4.参与(排名第二)国家自然科学基金面上项目:一维纳米材料与基底之间吸附能的定量测量及其机理研究(No. 11674399) 项目起止年月:2017.01-2020.12
获奖情况
1.2024年湖南师范大学教学创新案例大赛二等奖。
2.2010年湖南师范大学第十届青年教师课堂教学艺术竞赛二等奖。
3.2009年湖南师范大学第九届青年教师课堂教学艺术竞赛三等奖。
4. 2009 年湖南师范大学物理与信息科学学院第九届青年教师课堂教学艺术竞赛一等奖。
5.2007年湖南师范大学物理与信息科学学院第八届青年教师课堂教学艺术竞赛二等奖。
6.2005年湖南师范大学第七届青年教师课堂教学艺术竞赛三等奖。
7.2005年湖南师范大学物理与信息科学学院第七届青年教师课堂教学艺术竞赛一等奖。
8.2003-2004学年度湖南师范大学校级教学优秀奖。
代表性论文:
1.Hassan S U, Zafar S,Hou L*, Qamar T H, Yang Y, Kuang D, Wang S*. Compositional Engineering and Microwave Absorption Tuning of C-Coated High-Entropy Alloy Nanoparticles via Vapor-Phase Synthesis [J]. Sci China Mater, 2025;https://doi.org/10.1007/s40843-025-3316-1.
2.Zai M, Yibibulla T, Shah M, Ai L, Yang Y, Hassan S U,Hou L, Wang S. Development of Electrostatic Dual-Carbon-Fiber Microgrippers for Precise 2D Patterning and 3D Stacking of Single Microparticles [J]. Small Methods, 2025; https://doi.org/10.1002/smtd.202401878 .
3.Ai L, Liu T, Zai M,Hou L, Wang S. Fabrication and electroadhesion properties of parylene-coated carbon fiber arrays [J]. Bioinspir Biomim, 2025, 20(1): 016003; https://dx.doi.org/10.1088/1748-3190/ad8c88.
4.Shah M, Wu Y, Chen S, Mead J L,Hou L, Liu K, Tao S, Fatikow S, Wang S. Recent advances in controlled manipulation of micro/nano particles: a review [J]. J Phys D: Appl Phys, 2025, 58(8): 083001; https://dx.doi.org/10.1088/1361-6463/ad9030.
5.Akhtar N, Song X, Liu R, Asif M, Mead J L,Hou L*, Wang S*. Optical microscopy-based bridging method to quantify roughness-dependent adhesion of ZnS nanobelts on silicon substrates in air [J]. Appl Phys Lett, 2024, 125: 251601; https://doi.org/10.1063/5.0236929.
6.Hassan S U,Hou L*, Yang Y, Qamar T H, Wang S. Optimizing the electromagnetic wave attenuation properties of carbon encapsulated FeCoNiCuMnx high entropy alloy nanoparticles [J].Carbon, 2024, 229: 119502; https://doi.org/10.1016/j.carbon.2024.119502.
7.Hassan S U, Yang Y, Qamar T H, Shah M, Khan I,Hou L, Wang S. Core-shell designed high entropy alloy CoNiFeCuV-C nanoparticles for enhanced microwave absorption [J]. Appl Phys Lett, 2024, 124(12): 121902;https://doi.org/10.1063/5.0201983
8.Hassan S U,Hou L, Kuang D, Wang S. Carbon Based Composite Materials for Microwave Absorption in Low Frequency S and C Band: A Review [J]. ChemNanoMat, 2024, 10: e202400406; https://doi.org/10.1002/cnma.202400406.
9.Hassan S U, Yang Y, Kuang D, Qamar T H, Zai M, Zafar S,Hou L, Wang S. Binary and ternary ferromagnetic alloy/C nanocapsules for improved X-band microwave absorption [J]. J Phys D: Appl Phys, 2024, 57(29): 295303; https://dx.doi.org/10.1088/1361-6463/ad3f2b.
10.Yang Y, Ul Hassan S, Zai M, Shah M, Zafar S,Hou L, Wang S. Compositional design of C-coated multi-elemental alloy nanoparticles for superior microwave absorption [J].J Alloys Compd, 2024, 988: 174316;https://doi.org/10.1016/j.jallcom.2024.174316
11.Liu L, Yibibulla T, Yang Y, Hassan S U,Hou L, Kuang D, Mead J L, Deng L, Wang S. Design and microwave absorption characteristics of porous lamellar hard carbon materials [J]. Microporous Mesoporous Mater, 2024, 369: 113041;https://doi.org/10.1016/j.micromeso.2024.113041
12.Yibibulla T,Hou L*, Mead J L, Huang H, Fatikow S, Wang S*. Frictional behaviour of one-dimensional nanomaterials: an experimental perspective [J]. Nanoscale Adv, 2024, 6: 3251–84; http://dx.doi.org/10.1039/D4NA00039K.
13.Hou L, Hou M, Yibibulla T, Mead J L, Fatikow S, Wang S, Huang H. Frictional shear stress of ZnO nanowires on natural and pyrolytic graphite substrates [J]. Friction, 2022, 10(12): 2059–2068;https://doi.org/10.1007/s40544-021-0577-2
14.Hou L, Gao Y, Yibibulla T, Huang H, Wang S. Young's modulus and thermal stability of individual Sb2O3 nanowires at elevated temperatures [J]. Phys Status Solidi -R, 2022, 16: 2200039;https://doi.org/10.1002/pssr.202200039.
15.Zhen X,Hou L*, Gao Y, Hou M, Wang S. Preparation and optical properties of sulfur-doped silicon oxide microbelts and microrods [J]. Physica E, 2022, 142: 115294;https://doi.org/10.1016/j.physe.2022.115294
16.宰民明,侯丽珍*,王世良.微米纤维杨氏模量的静电共振测量[J].大学物理, 2022, 41(12): 70-74. http://dxwl.bnu.edu.cn/CN/abstract/article_8628.shtml
17.Liu L, Kuang D,Hou L, Luo H, Deng L, Wang S. Synthesis and microwave absorption performance of layered hard carbon embedded with ZnO nanoparticles [J]. J Alloys Compd, 2022, 895: 162677. https://doi.org/10.1016/j.jallcom.2021.162677
18.Hou L, Zhen X, Liu L, Kuang D, Gao Y, Luo H, Deng L, Chen C, Wang S. Synthesis, thermal stability, magnetic properties, and microwave absorption applications of CoNi-C core-shell nanoparticles with tunable Co/Ni molar ratio [J]. Results in Physics, 2021, 22: 103893. https://doi.org/10.1016/j.rinp.2021.103893
19.Yu B,Hou L, Wang S, Huang H. The adhesion of a mica nanolayer on a single-layer graphene supported by SiO2 substrate characterised in air [J]. Nanotechnology, 2021, 32(4): 045701. http://dx.doi.org/10.1088/1361-6528/abbf25
20.Kuang D,Wang S,Hou L,Luo H,Deng L,Song M,He J,Huang H.Facile synthesis and influences of Fe/Ni ratio on the microwave absorption performance of ultra-small FeNi-C core-shell nanoparticles[J].Mater Res Bull,2020,126:110837. https://doi.org/10.1016/j. materresbull.2020.110837
21.Hou L, Lee Mead J, Wang S, Huang H. The kinetic frictional shear stress of ZnO nanowires on graphite and mica substrates [J]. Appl Surf Sci, 2019, 465: 584-90. https://doi.org/10.1016/j.apsusc.2018.09.143
22.Hou L, Zheng L, Wang S, Huang H. Young’s modulus of Sb2O3 micro- and nanowires determined accurately by a nanomanipulation-assisted thermal resonance method [J]. AIP Adv, 2019, 9(8): 085101. https://aip.scitation.org/doi/abs/10.1063/1.5109161
23.Wen X,Hou L*, Deng L, Kuang D, Luo H, Wang S. Facile fabrication of extremely small CoNi/C core/shell nanoparticles for efficient microwave absorber [J]. NANO, 2019, 14(7): 1950090. https://www.worldscientific.com/doi/abs/10.1142/S1793292019500905
24.Kuang D,Hou L*, Wang S, Luo H, Deng L, Mead J L, Huang H, Song M. Large-scale synthesis and outstanding microwave absorption properties of carbon nanotubes coated by extremely small FeCo-C core-shell nanoparticles [J]. Carbon, 2019, 153: 52-61. https://doi.org/10.1016/j.carbon.2019.06.105
25.Kuang D,Hou L*, Wang S, Luo H, Deng L, He J, Song M. Facile synthesis of Fe/Fe3C-C core-shell nanoparticles as a high-efficiency microwave absorber [J]. Appl Surf Sci, 2019, 493: 1083-1089. https://doi.org/10.1016/j.apsusc.2019.07.073
26.Yu B,Hou L,Wang S,Huang H.Environment-Dependent Adhesion Energy of Mica Nanolayers Determined by a Nanomanipulation-Based Bridging Method [J].Adv Mater Interfaces,2019,6(2):1801552. https://onlinelibrary.wiley.com/doi/abs/10.1002/admi.201801552
27.Kuang D,Hou L*, Wang S, Yu B, Deng L, Lin L, Huang H, He J, Song M. Enhanced electromagnetic wave absorption of Ni–C core-shell nanoparticles by HCP-Ni phase [J]. Mater Res Express, 2018, 5(9): 095013. http://stacks.iop.org/2053-1591/5/i=9/a=095013