[1] 一种石墨烯柔性传感器及其制造方法;
[2] 一种超滑基本结构、多级超滑结构、具有该结构的器件及其形成方法;
[3] 读写接触式磁盘的磁头、硬盘设备及转移方法。
[4] 一种滑动摩擦测量装置;
[5] 往复滑动摩擦测量测试平台。
[32] Yutao Li, Bozhao Wu, Wengen Ouyang*, Ze Liu† and Wen Wang‡, Experimental decoding and tuning electronic friction of Si nanotip sliding on graphene, Nano Letters, 2024. (IF=10.8, 1区)
[31] Wang, Ashu and Zeng, Lingyan and Wang, Wen, Strain relaxation and self-heating effects of fin AlGaN/GaN HEMTs, Semiconductor Science and Technology, 38, 1 2023.
[30] Wen Wang*, Yu Zhang, Ashu Wang, Effects of substrate on the nanoscale friction of graphene, Applied Physics Letter. 123, 241602 (2023)
[29] Wen Wang*, Xiao Huang, Yiqing Huang, Yang Wang*, Nanoscale friction of tetrahedral amorphous diamond-like carbon film after thermal annealing, Tribology International, 2023, 190: 109064. (IF=6.2, 1区)
[28] Wen Wang* , Yu Zhang, Zhihong Li, and Linmao Qian*. Controllable Friction on Graphene via Adjustable Interfacial Contact Quality. Advanced. Science. 2023, 2303013. (IF=15.1, 1区)
[27] W Wang*, D Dietzel, A Schirmeisen*. Control of Nanoscale Ripple Formation on Ionic Crystals by Atomic Force Microscopy. Tribology letters, 71, 28 (2023).
[26] Wen Wang*, Dirk Dietzel, Andre Schirmeisen*. Nanoscale Friction across the First Order Charge Density Wave Phase Transition of 1T-TaS2. ACS Appl. Mater. Interfaces, 2023, 15, 3, 4774–4780. (IF=9.5, 1区)
[25] Xiaolin Yang , Wen Wang*. Friction characteristics in graphene/MoS2 heterojunction. Surface Science 728 (2023) 122207.
[24] Wen Wang*, Xiang Zhou. Temperature-dependent friction coefficient on flat graphite plane. Surface Science 729 (2023) 122233.
[23] Wen Wang*, Xiang Zhou, Linmao Qian, and Q.-C. He. Effect of temperature-induced contact quality evolution on nanoscale friction. Physical Review B 106, 134103 (2022).
[22] Wen Wang∗, Haocheng Lei, Ashu Wang. Temperature dependence of nanoscale friction on topological insulator Bi2Se3 surfaces. Nanotechnology 33 (2022) 395706.
[21] Wang, Ashu, Lingyan Zeng, and Wen Wang. "Study on the GaN/AlGaN Piezotronic Effect Applied in Pressure Sensors." ECS Journal of Solid State Science and Technology 10.3 (2021): 037007.
[20] Wen Wang*, Dirk Dietzel, Andre Schirmeisen*. Thermal activation of nanoscale wear. Physical Review Letters, 2021, 126(19): 196101. (IF=8.385, 1区)
[19] Wen Wang*, Ashu Wang, Lingyan Zeng. Temperature effects on the nano-friction across exposed atomic step edges. AIP Advances, 2020, 10(8).
[18] Wen Wang, Dirk Dietzel*, Andre Schirmeisen*. Single-asperity sliding friction across the superconducting phase transition. Science Advances, 2020, 6(12) (IF=13.117, 1区)
[17] Tingting Yang*, Wen Wang, Yuehua Huang, Xin Jiang, and Xuanliang Zhao. Accurate Monitoring of Small Strain for Timbre Recognition via Ductile Fragmentation of Functionalized Graphene Multilayers. ACS Appl. Mater. Interfaces, 2020, 12(51) (IF= 8.758, 1区)
[16] Jie Cheng; Wen Wang*; Sheng Zhang. Tribological properties of vertically aligned carbon nanotube arrays and carbon nanotube sponge. AIP Advances, 2020, 10(12).
[15] Wen Wang, Dirk Dietzel, Andre Schirmeisen*. Lattice Discontinuities of 1T-TaS2 across First Order Charge Density Wave Phase Transitions. Scientific Reports, 2019, 9(1).
[14] Ashu Wang*, Lingyan Zeng, Wen Wang; Zhenghua Luo. Static and dynamic simulation studies on the AlGaN/GaN pressure sensor. Semiconductor Science and Technology. 2019, 34: 115022.
[13] Wen Wang; Xide Li*. Interlayer motion and ultra-low sliding friction in microscale graphite flakes. Europhysics Letters, 2019, 125 (26003).
[12] Wen Wang*, Jian Shen, Q. C. He*. Microscale superlubricity of graphite under various twist angles. Physical Review B, 2019 (99): 054103.
[11] Wang, Ashu, Lingyan Zeng, and Wen Wang. "Surface donor states-dependent bare surface barrier height and 2DEG density of AlGaN/GaN heterostructure exerted uniaxial stress." Materials Research Express 5.2 (2018): 025903.
[10] Wang, Ashu, Lingyan Zeng, and Wen Wang. "Modification of strain and 2DEG density induced by wafer bending of AlGaN/GaN heterostructure: Influence of edges caused by processing." AIP Advances 8.3 (2018).
[9] Wen Wang*, Shudu Yang and Ashu Wang. Strain induced highly oriented graphene wrinkles. Materials Research Express, 2017, 4 (7): 075601.
[8] Wang, Ashu, Lingyan Zeng, and Wen Wang. "Simulation of gate leakage current of AlGaN/GaN HEMTs: Effects of the gate edges and self-heating." ECS Journal of Solid State Science and Technology 6.11 (2017): S3025.
[7] Wang Ashu, Lingyan Zeng, and Wen Wang. "Three-dimensional steady and transient fully coupled electro-thermal simulation of AlGaN/GaN high electron mobility transistors: Effects of lateral heat dissipation and thermal crosstalk between gate fingers." AIP Advances 7.9 (2017).
[6] Wen Wang*, Shudu Yang and Ashu Wang*. Observation of the unexpected morphology of graphene wrinkle on copper substrate, Scientific Reports, 2017, 7 (1): 8244.
[5] Renxin Wang, Hongze Zhang, Wen Wang, Yushi Zhang, Yuan Liu, Wei Xu and Zhihong Li*. New insight into direct electrical characterization of graphene utilizing cleavage-based micro four probe. Journal of Physics D: Applied Physics, 2016, 49 (29): 295108.
[4] Wen Wang, Tingting Yang, Hongwei Zhu*, and Quanshui Zheng*. Bio-inspired mechanics of highly sensitive stretchable graphene strain sensors. Applied Physics Letter, 2015, 106 (17): 171903.
[3] Tingting Yang, Wen Wang, Hongze Zhang, Xinming Li, Jidong Shi, Yijia He, Quan-shui Zheng, Zhihong Li, Hongwei Zhu*. Tactile Sensing System Based on Arrays of Graphene Woven Microfabrics: Electromechanical Behavior and Electronic Skin Application. ACS Nano, 2015, 9 (11): 10867. (IF: 13.709, 1区)
[2] Ming Ma, Igor M. Sokolov, Wen Wang, Alexander E. Filippov, Quanshui Zheng, and Michael Urbakh*. Diffusion through Bifurcations in Oscillating Nano- and Microscale Contacts: Fundamentals and Applications. Physical Review X, 2015 5 (3): 031020. (IF: 14.385, 1区)
[1] Wen Wang, Shuyang Dai, Xide Li, Jiarui Yang, David J. Srolovitz & Quanshui Zheng. Measurement of the cleavage energy of graphite. Nature Communications, 2015, 6 (7853).(IF: 17.694, 1区)
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