赵传 讲师 硕士生导师

学科领域：机械工程、智能制造、光电信息、纳米技术等

电子邮箱: zhuan.zhao@gzhu.edu.cn

个人简介：

赵传，工学博士，2022年毕业于意大利帕多瓦大学（导师：Pelizzo Maria Guglielmina)，目前主要研究方向包括高端装备零部件表面强化与改性制造、纳米与光刻加工技术、偏振光学器件与光电探测器、材料粒子束改性（质子、中子、重离子）等研究。主持国家自然科学基金青年基金、广东省自然科学基金-面上项目等，以第一和通讯作者在Applied surface science、Journal of manufacturing process、Surface coating & technology、Ceramic internationals、Optical materials、Journal of alloy and compounds、Journal of Materials Research and Technology等期刊发表SCI论文26篇，其中JCR 1区18篇。

工作经历:

◆2024.08–至今 广州大学 机械与电气工程学院  讲师

◆2022.07-2024.07   广州大学 物理与材料科学学院 师资博士后

主持/参与的科研项目:

[1] 国家自然科学基金-青年基金项目，12403084，Al/MgF₂反射式光栅设计与宽视场远紫外偏振性能研究，2025.01-2027.12，主持

[2] 广东省自然科学基金面上项目，2023A1515011079，基于TiN的混合等离子波导TM-pass偏振器制备及其中子辐射效应研究，2023.01-2025.1，主持

[3] 教育部产学合作协调育人项目，230802600302439，“新工科”背景下工业机器人核心零部件人才培养模式探索与实践，2024.01-2025.12，主持

[4] 广东佳博电子科技有限公司委托项目，键合丝关键工艺优化与技术支持，2024.08-2027.12，主持  

[5] 工业化和信息化部电子第五研究所委托项目，FinFET器件电应力加载电路板设计及制备，2025.09-2025.10，主持

[6] 广州市博士后科研项目资助，基于高吸收衬底的远紫外纳米光栅反射偏振器设计与制备研究，2022.07-2024.06，主持

[7] 广东省海上风电联合基金项目，基于激光-强化研磨加工的海上风电轴承滚道复合微结构创成与抗磨研究，2023A1515011723，2023.01-2026.12，参与

[8] 广东省自然科学基金面上项目，贵金属等离激元热空穴自刻蚀效应与SnO₂量子点超灵敏紫外光探测器研究，2023A1515012700，2023.01-2026.12，参与

[9] 国家自然科学基金，全息动载能场下具身机器人关节柔轮强化微纳改性调控与评价研究，52575615,2026.01-2029.12, 参与

代表性学术论文:

[1]Zhuan Zhao, Xincheng Xie, Gongbin Tang, Muhammad Amin Padhiar, Jinrui Xiao, Zhongwei Liang, Study on the effect of the strengthen grinding process surface coverage on the micro-morphology, micro-hardness, roughness, and residue stress of GCr15 bearing steels[J]. Journal of Manufacturing Processes, 99, 2023, 362-372. (中科院1区, JCR Q1, IF=6.2)

[2]Zhuan Zhao, Yunqi Zhong, Pei He, Qizhao Zhong, Yunmian Xiao, Seyed Ayoob Moosavi, Haowei Deng, Chang Cai,Enhancing wear resistance of Al0.5FeCoCrNi high-entropy alloy via Ti/Mo ratio-controlled precipitation and grain refinement,Tribology International,Volume 218,2026,111769. (中国科学院1区，IF=6.9)

[3]Zhuan Zhao, Weilong Chen, Xincheng Xie, Teng Ma, Shanshan Huang, Jinrui Xiao, Zhongwei Liang. Wear resistance of Cronidur 30 steel enhanced by optimizing the strengthened grinding process (SGP) parameters using a Box-Behnken design (BBD) method, Journal of Manufacturing Processes, 122,2024,.7-20.  (中科院1区, JCR Q1, IF=6.2)

[4] Xincheng Xie*, Zhihui Liu, Zhuan Zhao*. Improving the wear resistance of 440 C bearing steel balls through mechanical ball milling induced gradient structure[J]. Tribology International, 2024, 191: 109115. (中科院1区, JCR Q1, IF=6.2)

[5] Zhuan Zhao, Weilong Chen, Linqiang Wang, Teng Ma, Shusheng Pan. Enhanced UV photodetection in SnO₂ microwire arrays (MWAs) thin films by γ-ray irradiation[J]. Applied Surface Science, 2024: 160291. (中科院2区, JCR Q1, IF=6.7)

[6] Zhuan Zhao, Muhammad Amin Padhiar, Shaolin Zhang, Teng Ma, Noor Zamin Khan, Yongqiang Ji, Zubair Maroof, Shusheng Pan. Gamma Radiation-Induced Changes in the Structural and Optical Properties of CsPbBr3 Thin Films for space applications[J]. Ceramics International, 2024. (中科院2区, JCR Q1, IF=5.2)

[7] Zhuan Zhao, Hui Tang, Jinrui Xiao, Xiaochu Liu, Wengfeng Ding, Zhongwei Liang. "Ultrasonic strengthening grinding process induces α-Al₂O₃ adhesion to improve high temperature oxidation resistance of TA15 alloy." Surface and Coatings Technology, 2025,496: 131711. (中科院2区, JCR Q1, IF=6.2）

[8] Zhongwei Liang, Pei He, Zhuan Zhao, Yunqi Zhong, Zhenyan Li, Meicong Wang. Surface modification of 304 stainless steel by ultrasonic strengthening grind process with Al₂O_3-MoS₂-WC hybrid ceramic particles for wear resistance enhancement[J]. Surface and Coatings Technology,2025:132687.（中国科学院2区，JCR1区，IF=6.1）

[9] Zhongwei Liang, Wenhao Dou, Zhuan Zhao*, et al. Improved wear resistance of Ti-6Al-4V alloy by fabricating a SiC/Co composite layer through ultrasonic strengthening grinding process[J]. Results in Engineering, 2025: 108881. （中国科学院2区，JCR1区，IF=7.9）

[10] Zhuan, Zhao, Anqi Lin, Qiuhao Chen, Yunqi Zhong, Pei he, Wenhao Dou, Jinrui Xiao, Bokai Liao. Enhanced Corrosion Resistance of GCr15 Bearing Steel Via Ultrasonic Shot Peening with ZrO₂/Si₃N₄ Hybrid Media for in Situ Formation of Protective Si3N4 Coating and Oxide Layer. Met. Mater. Int. (2026). （中国科学院3区，JCR1区，IF=4）

[11] Abbas Nasir, Zhe Qin, Zhuan Zhao , Meicong Wang , Muhammad zakria , Yunqi Zhong , Teng Ma . Gamma-ray-induced enhancement of red emission in Ga_2-xEu_xO₃ phosphors for harsh radiative environment applications. Optical Materials, 2025, 117335.(中国科学院3区，JCR1区，IF=4.2）

[12] Noor Zamin Khan , Zhe Qin , Sayed Ali Khan , Anqi Lin , Zhuan Zhao , Muhammad Amin Padhiar , Zakir Ullah , Sonehra Anjum , Shimao Wang , Gang Meng. Neutron irradiation-enhanced orange-red emission in double perovskite phosphors for harsh radiation environments. Advanced Powder Technology, 2026, 105173. (中国科学院2区，JCR1区，IF=4.2）

[13] Zhuan Zhao, Wenkang Feng, Jinrui Xiao, Xiaochu Liu, Shusheng Pan, and Zhongwei Liang. Rapid and Accurate Prediction of Soil Texture Using an Image-Based Deep Learning Autoencoder Convolutional Neural Network Random Forest (DLAC-CNN-RF) Algorithm[J]. Agronomy, 2022, 12(12): 3063. (中科院2区, JCR Q1, IF=3.95)

[14] Xincheng Xie, Zhongning Guo*, Zhongwei Liang, Jinrui Xiao, Zhuan Zhao*. Enhanced high-temperature wear resistance of GCr15 steel balls by generating a Ti+Nb diffusion layer via mechanical alloying and NH₃·H₂O treatment[J]. Surface & Coatings Technology, 2023: 129632. (中科院1区, JCR Q1, IF=5.4)

[15] Jinrui Xiao, Yiteng Zhang, Xincheng Xie, Wenfeng Ding, Zhuan Zhao*, Zhongwei Liang*. Mechanical property improvement of wire-arc additive manufactured 06Cr19Ni9 steel based on ultrasonic strengthening grinding process[J]. Journal of Materials Research and Technology, 30, 2024: 7969-7980 (中科院2区, JCR Q1, IF=6.2)

[16] Xincheng Xie, Zhongning Guo, Jinrui Xiao, Zhongwei Liang, Shan Wei, Wenkang Feng, Zhuan Zhao*, and Xiaochu Liu*. Improved wear properties of GCr15 steel balls by fabricating a surface Ti diffusion layer using mechanical alloying and NH₃·H₂O treatment[J]. Journal of Materials Research and Technology, 2023, 22: 1961-1970. (中科院1区, JCR Q1, IF=6.26)

[17] Zhuan Zhao , You Wu , Weilong Chen , Jinrui Xiao, Teng Ma. Al2O3 and SiO2 doping on improving the gamma radiation resistance of optical fibers under different temperatures. Optical Fiber Technology, 2025, 104403.(中科院3区，JCR Q2，IF=2.8）

[18] Zhuan Zhao, Teng Ma, Jinrui Xiao, Zhihao Xu, Bingzhi Zhang*, and Shusheng Pan*. Compact and efficient wire grid reflecting polarizers at 121.6 nm[J]. Physica Scripta, 2022, 98(1): 015007. (中科院3区, JCR Q2, IF=2.9)

[19] Zhuan Zhao*, Corso Alain Jody, and Maria Guglielmina Pelizzo. Nanowire Grid Reflecting Polarizers for Ultraviolet Applications[J]. IEEE Photonics Journal, 2020, 12(6): 1-11. (中科院3区, JCR Q2, IF=2.88)

[20] Zhuan Zhao, Teng Ma, Haowei Deng, Seyed Ayoob Moosavi, Haoshi Zhang, Bingzhi Zhang, and Shusheng Pan*. Numerical demonstration of low-reflective wire grid polarizers with a patterned Fe₂O₃ absorptive layer[J]. Applied Optics, 2022, 61(32): 9708-9715. (中科院三区, JCR Q3, IF=1.9)

[21] Jinrui Xiao, Yiteng Zhang, Zhuan Zhao, Xincheng Xie, Zhongwei Liang. Improved wear resistance of 440C steel ball via ultrasonic strengthening grinding process. J. Mater. Process. Tech. 322 (2023) 118198.  (中科院1区, JCR Q1, IF=6.7)