Feb. 2021 – Present, Department of Mechanical Engineering, Tsinghua University, Assistant Professor
Aug. 2020 – Jan. 2021, Institute of Production Science, Karlsruhe Institute of Technology, Humboldt Research Fellow
Nov. 2019 – July. 2020, Department of Mechanical Engineering, Northwestern University, Postdoctoral Research Fellow
Oct. 2017 – Oct. 2019, Department of Mechanical and Automation Engineering, The Chinese University of Hong Kong, Postdoctoral Research Fellow
[1] Pang Y, Feng P, Wang J, et al. Performance analysis of the longitudinal-torsional ultrasonic milling of Ti-6Al-4V[J]. The International Journal of Advanced Manufacturing Technology. 2021: 1-12.
[2] Wang J, Liao W, Guo P. Modulated ultrasonic elliptical vibration cutting for ductile-regime texturing of brittle materials with 2-D combined resonant and non-resonant vibrations[J]. International Journal of Mechanical Sciences. 2020, 170: 105347.
[3] Wang J, Wang Y, Yang Y, et al. Fabrication of structurally colored basso-relievo with modulated elliptical vibration texturing[J]. Precision Engineering. 2020, 64: 113-121.
[4] Wang J, Yang Y, Zhu Z, et al. On ductile-regime elliptical vibration cutting of silicon with identifying the lower bound of practicable nominal cutting velocity[J]. Journal of Materials Processing Technology. 2020: 116720.
[5] Wang Y, Wang J, Chen A, et al. Structural coloration using face turning and variable tool vibration frequency[J]. Journal of Manufacturing Processes. 2020, 56: 1392-1396.
[6] Wang J, Yang R, Gao S, et al. Modulated vibration texturing of hierarchical microchannels with controllable profiles and orientations[J]. CIRP Journal of Manufacturing Science and Technology. 2020, 30: 58-67.
[7] Wang J, Yang Y, Yang R, et al. On the validity of compliance-based matrix method in output compliance modeling of flexure-hinge mechanism[J]. Precision Engineering. 2019, 56: 485-495.
[8] Wang J, Du H, Gao S, et al. An ultrafast 2-D non-resonant cutting tool for texturing micro-structured surfaces[J]. Journal of Manufacturing Processes. 2019, 48: 86-97.
[9] Wang J, Zhang J, Feng P, et al. Damage formation and suppression in rotary ultrasonic machining of hard and brittle materials: a critical review[J]. Ceramics International. 2018, 44(2): 1227-1239.
[10] Wang J, Zhang J, Feng P, et al. Experimental and theoretical investigation on critical cutting force in rotary ultrasonic drilling of brittle materials and composites[J]. International Journal of Mechanical Sciences. 2018, 135: 555-564.
[11] Wang J, Zhang J, Feng P, et al. Feasibility study of longitudinal–torsional-coupled rotary ultrasonic machining of brittle material[J]. Journal of Manufacturing Science and Engineering. 2018, 140(5).
[12] Wang J, Feng P, Zhang J. Reducing edge chipping defect in rotary ultrasonic machining of optical glass by compound step-taper tool[J]. Journal of Manufacturing Processes. 2018, 32: 213-221.
[13] Wang J, Feng P, Zhang J, et al. Experimental study on vibration stability in rotary ultrasonic machining of ceramic matrix composites: cutting force variation at hole entrance[J]. Ceramics International. 2018, 44(12): 14386-14392.
[14] Wang J, Feng P, Zhang J, et al. Reducing cutting force in rotary ultrasonic drilling of ceramic matrix composites with longitudinal-torsional coupled vibration[J]. Manufacturing letters. 2018, 18: 1-5.
[15] Wang J, Yang Y, Guo P. Effects of vibration trajectory on ductile-to-brittle transition in vibration cutting of single crystal silicon using a non-resonant tool[J]. Procedia Cirp. 2018, 71: 289-292.
[16] Feng P, Wang J, Zhang J, et al. Drilling induced tearing defects in rotary ultrasonic machining of C/SiC composites[J]. Ceramics International. 2017, 43(1): 791-799.
[17] Wang J, Feng P, Zhang J, et al. Investigations on the critical feed rate guaranteeing the effectiveness of rotary ultrasonic machining[J]. Ultrasonics. 2017, 74: 81-88.
[18] Wang J, Feng P, Zha T. Process monitoring in precision cylindrical traverse grinding of slender bar using acoustic emission technology[J]. Journal of Mechanical Science and Technology. 2017, 31(2): 859-864.
[19] Wang J, Feng P, Zhang J, et al. Experimental investigation on the effects of thermomechanical loading on the vibrational stability during rotary ultrasonic machining[J]. Machining Science and Technology. 2017, 21(2): 239-256.
[20] Wang J, Zhang J, Feng P. Effects of tool vibration on fiber fracture in rotary ultrasonic machining of C/SiC ceramic matrix composites[J]. Composites Part B: Engineering. 2017, 129: 233-242.
[21] Feng P, Wang J, Zhang J, et al. Research status and future prospects of rotary ultrasonic machining of hard and brittle materials[J]. J. Mech. Eng. 2017, 53: 3-21.
[22] Wang J, Zhang C, Feng P, et al. A model for prediction of subsurface damage in rotary ultrasonic face milling of optical K9 glass[J]. The International Journal of Advanced Manufacturing Technology. 2016, 83(1-4): 347-355.
[23] Wang J, Feng P, Zhang J, et al. Modeling the dependency of edge chipping size on the material properties and cutting force for rotary ultrasonic drilling of brittle materials[J]. International Journal of Machine Tools and Manufacture. 2016, 101: 18-27.
[24] Wang J, Zha H, Feng P, et al. On the mechanism of edge chipping reduction in rotary ultrasonic drilling: a novel experimental method[J]. Precision Engineering. 2016, 44: 231-235.
[25] Wang J, Feng P, Zheng J, et al. Improving hole exit quality in rotary ultrasonic machining of ceramic matrix composites using a compound step-taper drill[J]. Ceramics International. 2016, 42(12): 13387-13394.
[26] Wang J, Feng P, Zhang J. Investigations on the edge-chipping reduction in rotary ultrasonic machining using a conical drill[J]. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture. 2016, 230(7): 1254-1263.
[27] Wang J, Feng P, Zhang J. Reduction of edge chipping in rotary ultrasonic machining by using step drill: a feasibility study[J]. The International Journal of Advanced Manufacturing Technology. 2016, 87(9): 2809-2819.