主要研究方向

1、超精密切削加工工艺与切削机理研究

该方面代表性学术论文：

[1] Zhang L., Hashimoto T., Yan, J.* (2021) Machinability exploration for high-entropy alloy FeCrCoMnNi by ultrasonic vibration-assisted diamond turning. CIRP Annals - Manufacturing Technology, 70, 37-40.

[2] Wang C., Huang H.*, Zhang H.Y., Zhang L.*, Yan J.W. (2023) Laser repairing of FeCoCrNiV high-entropy alloy and its mechanical and cutting characteristics. Journal of Materials Processing Technology, 317, 118003.

[3] Zhang, L., Yi, A. Y, Yan, J.* (2022) Flexible fabrication of Fresnel micro-lens array by off-spindle-axis spiral diamond turning and precision glass molding. Precision Engineering, 74, 186-194.

[4] Zhang, L., Naples, N. J., Zhou W. C., & Yi, A. Y*. (2019) Fabrication of infrared hexagonal microlens array by novel diamond turning method and precision glass molding. Journal of Micromechanics and Microengineering, 29 (6).

[5] Zhang, L., Zhao, H. W., Dai, L., Yang, Y. H., Du, X. C., Tang, P. Y., & Zhang, L.* (2015) Molecular dynamics simulation of deformation accumulation in repeated nanometric cutting on single-crystal copper. RSC Advances, 5 (17), 12678-12685.

[6] Zhang, L., Huang, H., Zhao, H. W.*, Ma, Z. C., Yang, Y. H., & Hu, X. L. (2013) The evolution of machining-induced surface of single-crystal FCC copper via nanoindentation. Nanoscale Research Letters, 8 (1), 211.

[7] Zhang, L., Zhao, H. W.*, Yang, Y. H., Huang, H., Ma, Z. C., & Shao, M. K. (2014) Evaluation of repeated single-point diamond turning on the deformation behavior of monocrystalline silicon via molecular dynamic simulations. Applied Physics A, 116 (1), 141-150.

2、精密玻璃模压工艺与装备设计、优化、开发能力

该方面代表性学术论文：

[1] Zhang, L., Zhou W. C., & Yi, A. Y*. (2017) Rapid localized heating of graphene coating on a silicon mold by induction for precision molding of polymer optics. Optics Letters, 42 (7), 1369-1372.

[2] Zhang, L.*, Zolfaghari, A., Zhou, W. C., Shu, Y., Yi, A. Y. (2022) Flexible metallic mold based precision compression molding for replication of micro-optical components onto non-planar surfaces. Precision Engineering, 76, 149-159.

[3] Zhang, L.*, Yan, J. (2022) Study on nano-graphitic carbon coating on Si mold insert for precision glass molding. Surface and Coatings Technology, 128893.

[4] Zhang, L.*, Yi, A. Y. (2021) Investigation of novel mid-infrared rapid heating of carbide-bonded graphene coating and its applications on precision optical molding. Optics Express, 29, 30761-30771.

[5] Zhang, L.*, & Yi, A. Y. (2020) Manufacturing of a microlens array mold by a two-step method combining microindentation and precision polishing. Applied Optics, 59 (23), 6945-6952.

[6] Zhang, L., Zhou W. C., & Yi, A. Y*. (2018) Investigation of thermoforming mechanism and optical properties’ change of chalcogenide glass in precision glass molding. Applied Optics, 57 (22), 6358-6368.

[7] Zhang, L., Zhou W. C., Naples, N. J., & Yi, A. Y*. (2018) Investigation of index change in compression molding of As40Se50S10 chalcogenide glass. Applied Optics, 57 (15), 4245-4252.

3、复杂光学元件设计、加工与测试能力

该方面代表性学术论文：

[1] Zhang, L., Zhou, L., Zhou, W. C., Zhang, S. Q., & Yi, A. Y*. (2020) Design, fabrication and testing of a compact large-field-of-view infrared compound eye imaging system by precision glass molding. Precision Engineering, 66, 87-98.

[2] Zhang, L., Zhou W. C., Naples, N. J., & Yi, A. Y*. (2018) Fabrication of an infrared Shack–Hartmann sensor by combining high-speed single-point diamond milling and precision compression molding processes. Applied Optics, 57 (13), 3598-3605.

[3] Zhong, Y., Du, R.X., Zhang, L.*, Yi, A. Y. (2020) Structural colorization of surfaces with microstructures replicated by non-isothermal precision glass molding, Journal of Micro- and Nano-Manufacturing, 8, 041003.

[4] Zhou W. C., Zhang, L., & Yi, A. Y*. (2018) Design and Fabrication of a Compound-eye System using Precision Molded Chalcogenide Glass Freeform Microlens Arrays. Optik - International Journal for Light and Electron Optics, 171, 294-303.

4、材料表面激光微结构制造与功能化的能力（合作研究）

该方面代表性学术论文：

[1] Huang, H., Qian, Y., Zhang, L.*, Jiang, M., & Yan, J. (2022) A novel method for fabricating micro-dimple arrays with good surface quality on metallic glass substrate by combining laser irradiation and mechanical polishing under wax sealing, Journal of Manufacturing Processes, 79, 911-923.

[2] Huang, H., Hong, J., Qian, Y., Wang, C., Zhang, Z., & Zhang, L*. (2022) Nanosecond laser polishing of laser nitrided Zr-based metallic glass surface, The International Journal of Advanced Manufacturing Technology, 121, 4099-4113.

[3] Huang, H., Qian, Y., Zhang, L.*, Jiang, M., & Yan, J. (2022) A novel method for fabricating micro-dimple arrays with good surface quality on metallic glass substrate by combining laser irradiation and mechanical polishing under wax sealing. Journal of Manufacturing Processes, 79, 911-923.

[4] Huang, H., Hong, J., Qian, Y., Wang, C., Zhang, Z., & Zhang, L*. (2022) Nanosecond laser polishing of laser nitrided Zr-based metallic glass surface. The International Journal of Advanced Manufacturing Technology, 121, 4099-4113.

[5] Zhang, H., Qian, Y., Zhang, L., Zhang, D., Liu, H., & Huang, H*. (2021) Surface coloration of Zr-based metallic glass by nanosecond pulsed laser irradiation in ambient atmosphere. Materials Letters, 304, 130721.

[6] Zhang, L., & Huang., H*. (2019) Micro machining of bulk metallic glasses: a review. The International Journal of Advanced Manufacturing Technology, 100 (1-4), 637–661.