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综合介绍 General Introduction 个人相册

教育教学

个人经历 personal experience 工作经历 教育经历 2019.04 – 至今          西北工业大学，材料学院，副教授2018.01 – 2019.04    陕西师范大学，新能源高等技术研究院，副研究员2015.01 – 2018.01    中科院兰州化学物理研究所，助理研究员 2010.09 – 2014.07    中国科学院兰州化学物理研究所，博士2007.09 – 2010.06    西北师范大学，物理与电子工程学院，硕士2003.09 – 2007.07    山西大同大学，物理与电子科学学院，本科

荣誉获奖

教育教学 Education and teaching 招生信息 常年招收以下专业的博士研究生、硕士研究生和科研助理：材料科学与工程、化学、物理学、电子信息工程专业学生

科学研究

团队信息 Team Information 本人隶属于先进润滑与密封材料研究中心刘维民院士团队。西北工业大学先进润滑与密封材料研究中心成立于2017年3月，以中国科学院院士、“摩擦学最高成就奖”获得者刘维民教授为首席科学家，按照西北工业大学人才特区政策进行建设管理。中心依托学校材料科学与工程国家一级重点学科，以“建设一流科研环境，培养一流科技人才，做出一流科研成果”为最高目标。中心瞄准润滑材料及密封材料研究的国际前沿，面向国家重大需求，围绕材料学的基础科学问题，将材料学与润滑密封结合在一起，重点开展四个方向的研究：先进润滑材料、特种密封材料、材料表面/界面、功能纳米材料及应用。

学术成果

科学研究 Scientific Research 研究方向主要从事材料表界面的设计和加工方向的研究。研究内容为:(1) 柔性可印刷微型电源器件(2) 智能感知无线集成系统(3) 水下减阻材料设计与制备(4) 抗磨减摩水性涂层的设计与制备研究项目(1) 国家自然科学基金青年基金项目,“可全方位拉伸的仿生结构电极制备及其电化学电容性能研究”, 2016-01至2018-12, 主持.(2) “西部之光”人才培养计划西部青年学者B类，2016-01至2018-12, 主持.(3) 中央高校基本科研业务费，可穿戴式太阳能电池和超级电容器的一体化集成，2019-01至2020-12，主持.(4) 陕西省自然科学基础研究计划，一般项目（面上），可印刷在织物上的平面型微型超级电容器的研究，2020-01至2021-12，主持.(5) 固体润滑国家重点实验室开放课题，无序超滑表面湍流减阻性能研究，2020-01至2022-12, 主持.(6) 陕西省重点研发计划，国际科技合作计划项目-重点项目，可印刷平面型高能量锂/钠离子电池的制备及其形变下性能研究，2021-01至2023-12，参与.(7) 烟台先进材料与绿色制造山东省实验室应用技术开放基金，柔性基材表面化学镀铜及其应用技术开发研究，2022-01至2023-12, 主持. (8) 国家级项目，xx涂层技术，2021-04至2023-12，主持.(9) 国家级项目，微型Zn离子电池电学和耐机械形变性能研究，2023-07至2024-06，主持.

综合介绍

学术成果 Academic Achievements 1. 论文[40] Wang, H.; Dou, X.; Wang, Z.; Liu, Z.; Ye, Q.; Guo, R.*; Zhou, F.* Boosting Sensitivity and Durability of Pressure Sensors Based on Compressible Cu Sponges by Strengthening Adhesion of “Rigid‐Soft” Interfaces. Small 2023, 2303234.[39]胡倩; 高佳仪; 郭瑞生; 史俊勤; 王显宗. 微纳结构对阳极氧化铝超滑表面长期耐蚀性的影响机制研究. 中国腐蚀与防护学报 2023, 43 (4), 773-780.[38] Liu, F.*; Wang, X.; Ren, J.; Cao, W.; Guo, R.*; Zhao, W.; Jia, J. Microstructure and tribological properties evolution of Ni-Mo-SrSO4 composites as a function of Mo contents at different temperatures. Journal of Materials Research and Technology 2023, 24, 9834-9849.[37] Haoran Wang, Ruisheng Guo,* Yue Ma, and Feng Zhou, Cross-Doped Mn/Mo Oxides with Core-Shell Structures Designed by a Self-Template Strategy for Durable Aqueous Zinc-Ion Batteries, Adv. Funct. Mater. 2023, 2301351.[36] Zheng Wang, Jijun Ding,* and Ruisheng Guo,* Printable All-Paper Pressure Sensors with High Sensitivity and Wide Sensing Range, ACS Appl. Mater. Interfaces 2023, 15, 4789-4798.[35] Gong, P.; Lu, H.*; Yang, B.; Guo, R.; Zhang, S.; Zhu, R*. A Flexible, Foldable Metamaterial Absorber Fabricated by Matrix-Assisted Catalytic Printing. Progress In Electromagnetics Research Letters 2022, 105, 131-137.[34] Wang, Y.; Zhang, T.; Qiu, Y.; Guo, R.; Xu, F.; Liu, S.;* Ye, Q.;* Zhou, F. Nitrogen-Doped Porous Carbon Nanospheres Derived from Hyper-crosslinked Polystyrene as Lubricant Additives for Friction and Wear Reduction. Tribology International 2022, 107458.[33] Wang, H.; Xue, Y.; Song, X.; Lei, S.; Yu, H.; Du, C.-F.; Ren,* Z.; Guo, R.;* Zhou, F. Solid Solution Reinforced V3CrC3Tx MXene Cathodes for Zn-Ion Micro-Supercapacitors with High Areal Energy Density and Superior Flexibility. Journal of Materials Chemistry A, 2022, 10, 20953.[32] Chi Zhang#, Ruisheng Guo#*, Haoran Wang, Xudong Xie, Chengfeng Du*, Composite Electrodes with NiCoAl-LDH Coated Ti3C2Tx MXene and Incorporated Ag Nanowires for Screen-Printable In-Plane Hybrid Supercapacitors on Textiles, Applied Surface Science, 2022, 598 (2022) 153796.[31] Xin Song, Haoran Wang, Zhaoneng Li, Chengfeng Du,* Ruisheng Guo,* A Review of MnO2 Composites Incorporated with Conductive Materials for Energy Storage, The Chemical Record, 2022, e202200118.[30] H. Wang,# R. Guo,#* H. Li, J. Wang, C. Du, X. Wang,* Z. Zheng, 2D metal patterns transformed from 3D printed stamps for flexible Zn//MnO2 in-plane micro-batteries, Chemical Engineering Journal 429 (2022) 132196.[29] X. Xie, R. Guo,* B. Yang, H. Li, F. Yang, B. Shen,* Stencil-printed electrodes without current collectors and inactive additives on textiles for in-plane microsupercapacitors, Journal of Materials Chemistry A 9(44) (2021) 25042-25050.[28] J. Wang, J. Kang, Z.Y. Gu, Q. Liang, X. Zhao, X. Wang, R. Guo, H. Yu,* C.F. Du,* X.L. Wu,* Localized Electron Density Redistribution in Fluorophosphate Cathode: Dangling Anion Regulation and Enhanced Na‐Ion Diffusivity for Sodium‐Ion Batteries, Advanced Functional Materials (2021) 2109694.[27] R. Guo,# H. Li,# H. Wang, X. Zhao, H. Yu,* Q. Ye,* Polydimethylsiloxane-Assisted Catalytic Printing for Highly Conductive, Adhesive, and Precise Metal Patterns Enabled on Paper and Textiles, ACS Appl Mater Inter 13(47) (2021) 56597-56606.[26] W. Zhao, Z. Yao, R. Guo, F. Yu, G. Wu, S. Liu,* Low‐Temperature‐Processed CdS as the Electron Selective Layer in an Organometal Halide Perovskite Photovoltaic Device, Particle & Particle Systems Characterization 35(8) (2018) 1800137.[25] J. Chen,# B. Yang,# Y.D. Lim,# L. Su, J. Yang, R. Guo, B.K. Tay, X. Yan,* Field emission cathode based on three-dimensional framework carbon and its operation under the driving of a triboelectric nanogenerator, Nano Energy 49 (2018) 308-315.[24] B. Yang,# J. Chen,# S. Lei, R. Guo, H. Li, S. Shi, X. Yan,* Spontaneous Growth of 3D Framework Carbon from Sodium Citrate for High Energy- and Power-Density and Long-Life Sodium-Ion Hybrid Capacitors, Advanced Energy Materials 8(10) (2017) 1702409.[23] R. Guo, J. Chen, B. Yang, L. Liu, L. Su, B. Shen, X. Yan,* In-Plane Micro-Supercapacitors for an Integrated Device on One Piece of Paper, Advanced Functional Materials 27(43) (2017) 1702394.[22] L. Wu, J. Lang, P. Zhang, X. Zhang, R. Guo, X. Yan,* Mesoporous Ni-doped MnCo2O4 hollow nanotubes as an anode material for sodium ion batteries with ultralong life and pseudocapacitive mechanism, Journal of Materials Chemistry A 4(47) (2016) 18392-18400.[21] L. Wu, J. Lang, R. Wang, R. Guo, X. Yan,* Electrospinning Synthesis of Mesoporous MnCoNiOx@Double-Carbon Nanofibers for Sodium-Ion Battery Anodes with Pseudocapacitive Behavior and Long Cycle Life, ACS Appl Mater Inter 8(50) (2016) 34342-34352.[20] B.S. Shen, H. Wang, L.J. Wu, R.S. Guo, Q. Huang, X.B. Yan,* All-solid-state flexible microsupercapacitor based on two-dimensional titanium carbide, Chinese Chem Lett 27(10) (2016) 1586-1591.[19] B. Shen, X. Zhang, R. Guo, J. Lang, J. Chen, X. Yan,* Carbon encapsulated RuO2 nano-dots anchoring on graphene as an electrode for asymmetric supercapacitors with ultralong cycle life in an ionic liquid electrolyte, Journal of Materials Chemistry A 4(21) (2016) 8180-8189.[18] B. Shen, R. Guo, J. Lang, L. Liu, L. Liu, X. Yan, * A high-temperature flexible supercapacitor based on pseudocapacitive behavior of FeOOH in an ionic liquid electrolyte, Journal of Materials Chemistry A 4(21) (2016) 8316-8327.[17] X. Liu, R. Guo, Y. Shi, L. Deng, Y. Li,* Durable, Washable, and Flexible Conductive PET Fabrics Designed by Fiber Interfacial Molecular Engineering, Macromolecular Materials and Engineering 301(11) (2016) 1383-1389.[16] L. Liu, B. Shen, D. Jiang, R. Guo, L. Kong, X. Yan,* Watchband-Like Supercapacitors with Body Temperature Inducible Shape Memory Ability, Advanced Energy Materials  (2016) 1600763.[15] 郭瑞生, 魏强兵, 吴杨, 胡海豹, 周峰, 薛群基, 材料表面润湿性调控及减阻性能研究, 摩擦学学报 35(1) (2015) 23-30.[14] B. Shen, J. Lang, R. Guo, X. Zhang, X. Yan,* Engineering the Electrochemical Capacitive Properties of Microsupercapacitors Based on Graphene Quantum Dots/MnO2 Using Ionic Liquid Gel Electrolytes, ACS Appl Mater Interfaces 7(45) (2015) 25378-89.[13] R. Guo, Y. Yu, J. Zeng, X. Liu, X. Zhou, L. Niu, T. Gao, K. Li, Y. Yang, F. Zhou,* Z. Zheng,* Biomimicking Topographic Elastomeric Petals (E-Petals) for Omnidirectional Stretchable and Printable Electronics, Advanced Science 2(3) (2015) 1400021.[12] Y. Yu, J.F. Zeng, C.J. Chen, Z. Xie, R.S. Guo, Z.L. Liu, X.C. Zhou, Y. Yang, Z.J. Zheng,* Three-Dimensional Compressible and Stretchable Conductive Composites, Advanced Materials 26(5) (2014) 810-815.[11] X. Wang, C. Yan, H. Hu, X. Zhou, R. Guo, X. Liu, Z. Xie, Z. Huang, Z. Zheng,* Aqueous and air-compatible fabrication of high-performance conductive textiles, Chemistry-an Asian journal 9(8) (2014) 2170-7.[10] K. Li, H. Zhen, L. Niu, X. Fang, Y. Zhang, R. Guo, Y. Yu, F. Yan, H. Li, Z. Zheng,* Full-Solution Processed Flexible Organic Solar Cells Using Low-Cost Printable Copper Electrodes, Advanced Materials 26(42) (2014) 7271-7278.[9] R. Guo, H. Hu, Z. Liu, X. Wang,* F. Zhou,* Highly durable hydrophobicity in simulated space environment, RSC Advances 4(54) (2014) 28780.[8] T. Gao, S.-W. Ng, X. Liu, L. Niu, Z. Xie, R. Guo, C. Chen, X. Zhou, J. Ma, W. Jin, Y.-S. Chui, W. Zhang, F. Zhou,* Z. Zheng,* Transferable, transparent and functional polymer@graphene 2D objects, NPG Asia Mater 6 (2014) e130.[7] R. Guo, Y. Yu, Z. Xie, X. Liu, X. Zhou, Y. Gao, Z. Liu, F. Zhou, Y. Yang, Z. Zheng,* Matrix-Assisted Catalytic Printing for the Fabrication of Multiscale, Flexible, Foldable, and Stretchable Metal Conductors, Advanced Materials 25(24) (2013) 3343-3350.[6] M. Cai, R. Guo, F. Zhou, W. Liu,* Lubricating a bright future: Lubrication contribution to energy saving and low carbon emission, Sci. China Technol. Sci. 56(12) (2013) 2888-2913.[5] L.Q. Wang, C.W. Wang,* J.B. Chen, R.S. Guo, F. Zhou, W.M. Liu, Electron field emission from the carbon-doped TiO2 nanotube arrays, Thin Solid Films 519(22) (2011) 8173-8177.[4] R.S. Guo, C.W. Wang,* J.B. Chen, J.A. Wang, L.Q. Wang, W.M. Liu, Field emission from TiO2/Ti nanotube arrays with different morphologies, Physica B 405(22) (2010) 4682-4686.[3] J.-B. Chen, C.-W. Wang,* R.-S. Guo, L.-Q. Wang, W.-D. Zhu, F. Zhou, W.-M. Liu, Fabrication and field emission of carbon nanotubes/TiO2/Ti composite nanostructures, Journal of vacuum science & technology. B, Microelectronics and nanometer structures 28(6) (2010) 1274.[2] J.-B. Chen, C.-W. Wang,* J. Wang, Y. Li, R.-S. Guo, B.-H. Ma, F. Zhou, W.-M. Liu, Synthesis and field emission of diamond-like carbon nanorods on TiO2/Ti nanotube arrays, Applied Surface Science 256(1) (2009) 39-42.[1] J.-B. Chen, C.-W. Wang,* B.-H. Ma, Y. Li, J. Wang, R.-S. Guo, W.-M. Liu, Field emission from the structure of well-aligned TiO2/Ti nanotube arrays, Thin Solid Films 517(15) (2009) 4390-4393.2. 专利[1] 郭瑞生; 李昊东; 王浩然; 一种柔性的导电金属图案及其制备方法、应用和导电材料, 2021-03-09, 中国, 202110252898.1. (授权)[2] 郭瑞生; 李昊东; 宋昕; 窦小强; 一种导体的制备方法、柔性金属导体、应用和导电材料, 2021-10-29, 中国, 202111268401.1. (专利受理)[3] 郭瑞生; 谢雯; 王浩然; 李昭能; 一种用于Zn离子电池正极的聚苯胺复合材料的制备方法, 2022-09-23, 中国, 202211178126.9. (专利受理)[4] 郭瑞生; 窦小强; 刘旭庆；一种基于树脂粘结剂制备柔性金属导体的方法, 2022-12-22, 中国, 202211658309.0. (专利受理)[5] 郭瑞生；程思远；汤国中；黄小磊；秸秆纤维滑石粉改性聚乙烯吹膜级复合材料及其制备方法，2023-02-16, 中国，202310122320.3. (专利受理)