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- 2024年.
- [1]Miao Yu1, Lida Zhu1,*, et al. In-Situ Monitoring and Innovative Feature Fusion Neural Network for Enhanced Laser Directed Energy Deposition Track Geometry Prediction and Control[J]. IEEE Transactions on Instrumentation & Measurement, 2024. (SCI JCR Q1). IF=5.6.
- [2]Zongze Jiang1, Lida Zhu1,*, et al. Influence of ultrasonic vibration on molten pool behavior, cladding layer microstructure and pore defects for directed energy deposition[J]. Applied Thermal Engineering, 2024, 247(15): 123047. (SCI JCR Q1). IF=6.4.
- [3]Ning JinSheng1, Zhu Lida1,*, et al. Printability Differences Induced by Heterogeneous Material Combinations: A Comparative Investigation by Directed Energy Deposition[J]. International Journal of Extreme Manufacturing, 2024(6): 025001. (SCI JCR Q1). IF=14.7.
- [4]Hao Lu1, Lida Zhu1,*, et al. Ultrasonic machining response and improvement mechanism for differentiated bio-CoCrMo alloys manufactured by directed energy deposition[J], J Mater Sci Technol.2024. (SCI JCR Q1) IF=10.9.
- [5]Pengsheng Xue, Yichao Dun, Lida Zhu*, et al. The effect of heterogeneous microstructure of additively manufactured Ni2CoCrNb0.16 high-entropy alloy on its machinability and tool wear[J], Tribology International, 2024(191):109160, (SCI JCR Q1) IF=6.2.
- [6]Peihua Xu1, Lida Zhu1,*, et al. Anisotropy behavior of liquid metal elastomer composites with both enhanced thermal conductivity and crack resistance by direct ink writing[J], Composites Part A: Applied Science and Manufacturing, 2024(177):107890, (SCI JCR Q1) IF=8.7.
- [7]Shaoqing Qin1, Lida Zhu1,*. Surface and subsurface damage of laser assisted grinding CrCoNi medium-entropy alloy at atomic/nano scale[J], Tribology International, 2024(191):109121, (SCI JCR Q1) IF=6.2.
- [8]Jinsheng Ning, Yunhang Zhao, Lida* Zhu, et al. Height consistency compensation in laser-directed energy deposition of thin-walled parts[J]. International Journal of Mechanical Sciences, 2024, 266: 108963. (SCI JCR Q1). IF=7.3.
- 2023年.