教育及工作经历:
2014年4月-2017年3月 日本高知工科大学 工学博士
2017年6月-2019年10月 山东省科学院 助理研究员
2019年11月-至今 山东交通学院 讲师
研究方向:
无人机结构设计;光电纳米材料设计及仿真模拟;柔性太阳能电池研究。
科研项目:
(1)国家自然科学基金青年基金,分级多孔PI-ZrO2-PI复合纳米纤维超薄膜制备及对高温PM2.5的过滤研究,参与。
(2)山东省自然科学基金, 过冷水滴在疏水表面的运动特征及结冰过程研究,参与
(3)山东省自然科学基金,面向糖尿病酮症酸中毒无创诊断的光辅助复合钙钛矿/氧化铟基丙酮气体传感器研究,参与
(4) 企业委托项目, 山地巡逻无人机结构设计, 主持
(5) 企业委托项目,高效太阳能发电电化学储能一体化技术开发, 主持
(6) 企业委托项目,新型电网储能电池试验检测技术开发, 主持
(7)企业委托项目, 2024060, 环保自修复水泥基材料制备方法开发, 主持
发表文章:
(1)C. Ren; S. Hou. Optimising the Workability of Cement-based Coatings: Synergistic Effects of the Particle Size, Water Reducer and Silica Fume, Ceramics-silikaty, 2025, 69(4):
(2)R. Gao; S. Hou. Optical Properties of Formation of Gold Nanoparticle Aggregates Deposited on Quartz Glass and Application to SPR Sensing, Optical Properties, 2022, 125(无)
(3) Q. Zhang; S.Hou. Titanium Dioxide-Coated Zinc Oxide Nanorods as an Efficient Photoelectrode in Dye-Sensitized Solar Cells, Nanomaterials, 2020, 10(8).
(4)S. Hou, C. Li. “Aluminum-doped zinc oxide thin film as seeds layer effects on the alignment of zinc oxide nanorods synthesized in the chemical bath deposition”. Thin Solid Films, 2016, 605(605): 37-43.
(5) S. Hou, C. Li. “Fabricated ZnO Nanorods on Transparent Conductive Ga-Doped ZnO Film as Photoanodes Applying for Dye-Sensitized Solar Cell”. Nanoscience and Nanotechnology Letters, 2016, 8(7): 561-566.
(6) S. Hou, C. Li. “Controllable ZnO Nanorods Growth by Chemical Bath Deposition”. Transactions-Materials Research Society of Japan, 2015, 40(2): 187-190.
(7) S. Hou, L. Xie, C. Li. “Dependence of ZnO Nanostructures Fabricated on the Different Substrates by a Novel Annealing Method”. IEICE Technical Report:electronic Information, 2017.
(8) J. Udorn, S. Hou, C. Li, A. Hatta, H. Furuta. “CdSeZnS Quantum Dot (QD) Sensitized Solar Cell Utilizing a Multi-Walled Carbon Nanotube Photoanode on a Stainless Steel Substrate”. International Journal of Electrochemical Science. 2017, 12: 3814–3825.
(9)X. Li, C. Li, S. Hou, A. Hatta, J. Yu, N. Jiang. (2015). Thickness of ITO thin film influences on fabricating ZnO nanorods applying for dye-sensitized solar cell. Composites Part B: Engineering, 74, 147-152. “Thickness of ITO thin film influences on fabricating ZnO nanorods applying for dye-sensitized solar cell”. Composites Part B: Engineering . 2015, 74: 147-152.
(10)C. Li, S. Hou. “Well-controllable Fabrication of Aligned ZnO Nanorods for Dye-sensitized Solar Cell Application”. MRS Proceedings, 2015.
