王继强科研成果

个人简介 学术成果 新建主栏目 基本信息 名称 王继强，男，工学博士，1994年出生于吉林省榆树市。入选哈尔滨工业大学“春雁英才计划”，哈工大机电工程学院助理教授。 研究方向为基于原子力显微镜的纳米铣削加工、检测及应用。以第一作者（二作导师一作）在International Journal of Machine Tools and Manufacture、CIRP annals-Manufacturing Technology、International Journal of Mechanical Sciences等期刊发表SCI论文18篇。曾获得博士研究生国家奖学金、黑龙江省三好学生和黑龙江省优秀毕业生等荣誉。 工作经历 标题 工作单位 哈尔滨工业大学 职位/职称 助理教授 起讫时间 2023.07-至今 简单介绍 教育经历 标题 起讫时间 2019.09-2023.06 所学专业 机械工程 学习机构 哈尔滨工业大学 学历 博士 简单介绍 标题 起讫时间 2017.09-2019.06 所学专业 机械制造及其自动化 学习机构 哈尔滨工业大学 学历 硕士 简单介绍 标题 起讫时间 2013.09-2017.06 所学专业 机械工程 学习机构 东北大学秦皇岛分校 学历 学士 简单介绍 荣誉称号 称号名称 黑龙江省优秀毕业生 获奖时间 2023 获奖地点 简单介绍 称号名称 The 8th International Conference on Nanomanufacturing & the 4th AET Symposium on ACSM and Digital Manufacturing ‘Best Paper Award’. 获奖时间 2022 获奖地点 简单介绍 称号名称 博实博士生一等奖学金 获奖时间 2022 获奖地点 简单介绍 称号名称 博士研究生国家奖学金 获奖时间 2021 获奖地点 简单介绍 称号名称 黑龙江省三好学生 获奖时间 2019 获奖地点 简单介绍 期刊论文 名称 [1] Wang J Q, Yan Y D, Li Z H, Geng Y Q. Towards understanding the machining mechanism of the atomic force microscopy tip-based nanomilling process. International Journal of Machine Tools and Manufacture, 2021, 162: 103701. [2] Yan Y D(导师), Wang J Q, Geng Y Q, Zhang G X. Material removal mechanism of multi-layer metal-film nanomilling. CIRP Annals-Manufacturing Technology, 2022, 71: 61-64. [3] Wang J Q, Yan Y D, Geng Y Q. Fabrication of Chiral Nanostructures through Vibration-Assisted Scratching Combined with Wet Etching for Surface-Enhanced Raman Scattering Substrates. ACS applied nano materials, 2023, 6, 5860-5870. [4] Wang J Q, Yan Y D, Li C, Geng Y Q. Material removal mechanism and subsurface characteristics of silicon 3D nanomilling. International Journal of Mechanical Sciences, 2023, 242:108020. [5] Wang J Q, Zhang Q, Yan Y D, Liu Y, Geng Y Q. Fabrication of periodic nanostructures for SERS substrates using multi-tip probe-based nanomachining approach. Applied Surface Science, 2022, 576:151790. [6] Wang J Q, Yan Y D, Li Z H, Geng Y Q, et al. Processing outcomes of atomic force microscope tip-based nanomilling with different trajectories on single-crystal silicon. Precision Engineering, 2021, 72: 480-490. [7] Wang J Q, Yan Y D, Li Z H, Geng Y Q, et al. Study on the vertical ultrasonic vibration-assisted nanomachining process on single-crystal silicon. Journal of Manufacturing Science and Engineering-Transactions of the ASME, 2022, 144: 041013. [8] Wang J Q, Yan Y D, Jia B S, et al. Study on the processing outcomes of the atomic force microscopy tip-based nanoscratching on GaAs. Journal of Manufacturing Process, 2021, 70: 238-247. [9] Wang J Q, Yan Y D, Chang S Y, et al. Study of the formation mechanism of bundle structures using AFM tip-based nanoscratching approach. Tribology International, 2020, 142: 106000. [10] Wang J Q, Yan Y D, Chang S Y, et al. Label-free surface-enhanced Raman spectroscopy detection of absorption manner of lysozyme based on nanodots arrays. Applied Surface Science, 2020, 509:145332. [11] Wang J Q, Wang Y Z, Yan Y D, Geng Y Q. Fabrication of periodic nanostructure using a multi-tip diamond tool: depth prediction and material removal mechanism. The International Journal of Advanced Manufacturing Technology, 2022, 123, 3485-3496. [12] Wang J Q, Zhang Q, Yan Y D, Kong D P, Geng Y Q. Surface-enhanced Raman scattering integrated with microfluidic device fabricated using atomic force microscopy tip-based nanomachining approach. Proc IMechE Part B: J Engineering Manufacture, 2022, 1-12. [13] Wang J Q, Yan Y D, Wang S W, Shi W B, Geng Y Q. A probe-based nanometric morphology measurement system using intermittent-contact mode. Review of Scientific Instruments, 2022, 93:113701. [14] Geng Y Q(副导师), Wang J Q, Li Z H, Yan Y D, Zhang J R, Gan Y. Comparison of the indentation processes using the single indenter and indenter array: A molecular dynamics study. Nanoscale Research Letters, 2022, 14: 49. [15] Geng Y Q(副导师), Wang J Q, Yan Y D, et al. Fabrication of nanoindentation array based SERS substrate using Conical and Berkovich indenters. Proc IMechE Part C: J Mechanical Engineering Science, 2023, 1-13. [16] Yan Y D(导师), Wang J Q, Chang S Y, et al. Nanofluidic devices prepared by an atomic force microscopy-based single-scratch approach. RSC Advances, 2019, 9: 38814 [17] Yan Y D(导师), Wang J Q, Geng Y Q, et al. Implementation of AFM tip-based nanoscratching process on single crystal copper: Study of material removal state. Applied Surface Science, 2018, 459: 723-731. [18] Wang J Q, Yan Y D, Geng Y Q, et al. Fabrication of polydimethylsiloxane nanofluidic chips under AFM tip-based nanomilling process. Nanoscale Research Letters, 2019, 14: 136. [19] 王继强, 耿延泉, 闫永达. 基于AFM纳米机械刻划加工纳米结构及应用. 自然杂志, 2020, 42(3): 210-220. 会议论文 名称 [1] Wang J Q, Geng Y Q, Yan Y D, Li Hao. Study on the effects of processing parameters on machining outcomes under AFM tip-based nanomilling approach [C]// Proceedings of the 8th International Conference on Nanomanufacturing & 4th AET Symposium on ACSM and Digital Manufacturing, 2022. [2] Wang J Q, Geng Y Q, Jia J S, Yan Y D. A large-scale nanomachining system established based on AFM contact mode [C] // The 9th International Conference of Asian Society for Precision Engineering and Nanotechnology, 2022. 专利 专利名称 基于AFM纳米铣削及化学腐蚀加工的表面增强拉曼基底制备方法 专利号 CN114411152A 发明人 耿延泉, 王继强, 闫永达. 申请时间 2022.04.29 专利类别 发明 简单介绍 专利名称 一种基于AFM的微纳流控芯片制备方法 专利号 ZL 201811002922 发明人 耿延泉, 王继强, 闫永达. 申请时间 2020.08.28 专利类别 发明 简单介绍