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唐弓斌

2024/09/03  点击:[]

唐弓斌

博士、副教授

研究领域:机械摩擦学与表面技术、机器学习、第一性原理计算

办公地点:创新大楼A栋

电子邮箱: gbtang@gzhu.edu.cn

团队每年招收硕士/博士研究生数名(欢迎有志读博的同学报考)


个人简介:

唐弓斌,工学博士,毕业于华南理工大学机械与汽车工程学院(导师苏峰华教授),目前研究方向主要包括装备表面耐磨控制与腐蚀防护第一性原理计算/分子动力学模拟机器学习、高熵合金摩擦与力学性能调控等。担任中国机械工程学会摩擦学分会青年委员、广东省机械工程学会摩擦学分会理事。主持国家自然科学基金-青年科学基金、中国博士后科学基金-面上项目、广东省自然科学基金-青年基金等;参与国家重点研发计划项目、国家自然科学基金面上项目、广东省海上风电联合基金-重点项目、JW科技委及ZB预研装共用技术等课题。以第一作者/通讯作者在Nano Lett、Chem Eng J、Carbon、Tribol Int、Wear及Appl Surf Sci等权威期刊发表SCI收录论文20余篇,指导/协助指导博士生2人、硕士生12人。

工作经历:

2024-至今 广州大学 机械与电气工程学院 副教授

2022-2024 广州大学 机械与电气工程学院 师资博士后

教授课程:

机械设计基础》、《智能传感与检测技术》等

主持/参与的研究项目:

[1]国家自然科学基金 青年科学基金项目,52405179,基于富氮强化研磨的轴承套圈氮化机理及摩擦学性能研究,2025.01-2027.12,30万,主持

[2]广东省基础与应用基础研究基金委员会 粤穗联合-青年项目,2023A1515110290,等离子体辅助含氢类富勒薄膜奇数碳环的形成机制及其摩擦学性能研究,2023.11-2026.10,10万,主持

[3]中国博士后科学基金面上项目,基于强化研磨富氮层的形成机制及摩擦磨损行为研究,2022M720871,2022.11-2024.06,8万,主持

[4]滨州魏桥国科高等技术研究院,基于强化改性研磨铝合金表面防腐与耐磨控制研究,2022.09-2023.09,10万,主持

[5]工业摩擦润滑技术国家地方联合工程研究中心开放基金,海上风电轴承润滑脂劣化机理及摩擦磨损行为研究,2023.01-2024.06,主持

[6]科技部国家重点研发专项,智能餐厅机器人关键技术与装备集成示范2023YFD2101004,2023.12-2027.11,2000万,参与

[7]广东省基础与应用基础研究基金委员会-海上风电联合基金-重点项目,海上风电装备关键零部件失效机理与强化改性研磨控制方法研究,2022.10-2026.09,100万,主要参与人


研究成果:

1.近期发表的代表性期刊论文

[1]Tang Gongbin, Su Fenghua*, Xu Xing, Chu Paul K. 2D black phosphorus dotted with silver nanoparticles: An excellent lubricant additive for tribological applications [J]. Chemical Engineering Journal, 2020, 392: 123631.(中科院一区top,IF=13.3,ESI高被引

[2]Tang Gongbin, Wu Zhibin, Su Fenghua*, Wang Haidou, Xu Xing, Li Qiang, Ma Guozheng*, Chu Paul K. Macroscale Superlubricity on Engineering Steel in the Presence of Black Phosphorus [J]. Nano Letters, 2021, 21(12): 5308-5315.(中科院一区top,IF=10.8

[3]Xu Xing, Wan Bingbing, Li Wenfang*, Liu Fenghua, Zhai Tongguang, Zhang Lijuan, Tang Gongbin*. Reaction mechanisms for Ti coatings on diamond [J]. Carbon, 2024, 226: 119206.(中科院二区top,IF=10.5)

[4]Tang Gongbin*, Ou Zixin, Liu Fenghua, Li Tao, Su Fenghua, Zheng Jiapeng*, Liang Zhongwei*. Enhancing wear resistance of aluminum alloy by fabricating a Ti-Al modified layer via surface mechanical attrition treatment [J]. Tribology International, 2024, 193: 109462.(中科院一区top,IF=6.1)

[5]Zheng Jiapeng, Tang Gongbin*, Su Fenghua, Li Tao, Liang Zhongwei, Liu Xiaochu*. Facile fabrication of aluminium alloys with gradient nanostructures incorporating α-Al2O3 particles for enhanced tribological properties [J]. Tribology International, 2023, 189: 108921.(中科院一区top,IF=6.1)

[6]Li Shaoyang, Tang Gongbin*, Zou Tao, Wang Jingwen, Ou Zixin, Lin Hai, Su Fenghua, Liang Zhongwei*. Enhancing tribological properties of 18CrNiMo7-6 through grain refinement incorporating Al2O3 particles [J]. Tribology International, 2023, 190: 109045.(中科院一区top,IF=6.1)

[7]Tang Gongbin, Hu Haobing, Huang Zongbi, Pan Yiting, Zou Tao, Liang Zhongwei*, Wang Jingwen*, Su Fenghua. Facile fabrication of Co-containing coating to enhance the wear resistance of 24CrNiMo steel at elevated temperature [J]. Wear, 2024, 554-555: 205484.(中科院一区top,IF=5.3)

[8]Hu Haobing, Tang Gongbin*, Cheng Zhitao, Pan Yiting, Huang Zongbi, Ding Wenfeng, Liang Zhongwei*. Co-Cr3C2 coating incorporating grain refinement and dislocation density gradient to enhance wear resistance of 24CrNiMo steel [J]. Wear, 2025, 564-565: 205752. 中科院一区top,IF=5.3)

[9]Tang Gongbin, Yang Jinfeng, Huang Zongbi, Li Jiahao, Yang Maoli, Hu Haobing*, Liang Zhongwei*. Grain refinement of CoCrFeNiMn high-entropy alloy for improved high-temperature tribological properties [J]. Journal of Alloys and Compounds, 2025, 1014: 178853.(中科院二区top,IF=5.8

[10]Tang Gongbin*, Sun Shulong, Yang Jinfeng, Pan Yiting, Liu Zhicheng, Liang Zhongwei*. Fabrication and tribological properties of WC-reinforced Inconel X-750 alloy at elevated temperature [J]. Journal of Manufacturing Processes, 2024, 131: 1321-1333.(中科院一区top,IF=6.1)

[11]Tang Gongbin, Su Fenghua*, Liu Xiaochu, Liang Zhongwei, Zou Tao, Chu Paul K. Origin of superlubricity promoted by black phosphorus dotted with gold nanoparticles [J]. Applied Surface Science, 2023, 613: 156030.(中科院二区top,IF=6.3)

[12]Tang Gongbin, Su Fenghua*, Liu Fenghua, Liu Zhicheng, Li Qiang, Chen Yanjun, Liang Zhongwei*, Chu Paul K*. Atomic-scale evolution of hydrogenated fullerene-like carbon in the presence of black phosphorus [J]. Applied Surface Science, 2024, 652: 159322.(中科院二区top,IF=6.3)

[13]Xie Xincheng, Ye Yu, Zou Zhixiang, Mo Yuandong, Liang Zhongwei*, Tang Gongbin*. Improving the corrosion resistance of aluminum alloy welds through powder-ball combined ultrasonic shot peening [J]. Journal of Materials Processing Technology, 2024, 332: 118557. (中科院二区top,IF=6.7)

[14]Tang Gongbin, Liu Zhicheng, Qin Chudong*, Pan Yiting, Liang Zhongwei*, Su Fenghua. Atomic-scale insights into degradation mechanisms of lithium-based grease at high temperatures [J]. Surfaces and Interfaces, 2025, 56: 105692.(中科院二区top,IF=5.7)

[15]Chen Ke, Pan Yiting, Tang Gongbin*, Liang Dongyang, Hu Haobing, Liu Xiaochu, Liang Zhongwei*. Facile fabrication of TiN coatings to enhance the corrosion resistance of stainless steel [J]. Surface and Coatings Technology, 2024, 494: 131450.(中科院二区top,IF=5.4

[16]Tang Gongbin, Li Shiyuan, Yang Jinfeng, Zhou Xinyu, She Rongbing, Li Dongwei, Zou Tao, Wang Jingwen*, Liang Zhongwei*. Gradient hardening of Ni-based superalloy K403 for enhanced thermal fatigue resistance [J]. Surface and Coatings Technology, 2024, 478: 130434.(中科院二区top,IF=5.4


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