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姓名： 陈瑶

性别：男

出生年月：1970.04

学历：    研究生     学位：博士

职称／导师类别：博导/硕导

毕业学校： 北京航空航天大学

学科专业： 材料加工工程

主要研究

方向

激光增材制造生物降解骨组织支架及性能

高温耐磨涂层、生物涂层设计及等离子喷涂制备

一维/二维碳纳米材料增强金属基/陶瓷基复合材料

科研工作简历

• 2010年1月-至今：苏州大学 best365体育，特聘教授，博士生导师

• 2008年8月-2010年8月;日本 大阪大学 接合科学研究所，JSPS（日本学术振兴会）特别研究员

• 2006年4月-2008年7月：美国 佛罗里达国际大学 机械与材料工程系，博士后

• 2004年11月-2006年3月：中国科学院力学研究所，博士后

• 1999年9月-2004年10月：北京航空航天大学 材料科学与工程学院，工学博士

学术成果

（论文、著作、获奖、专利等情况）

作为项目负责人，主持/完成装备预研国防基金、国家自然科学基金面上项目(No.51471113、51275326、50471088)、江苏省科技支撑（工业）项目（BE2013062）、江苏省自然科学基金项目（BK2010212）、日本学术振兴会(JSPS)资助项目(P0878)及企业委托项目20余项；参与完成美国NASA资助项目、美国Office of Naval Research资助项目、美国NSF资助项目、中国科学院“知识创新工程”重大项目（KGXX-11）等项目。

研究成果在ACS Applied Materials & Interfaces、Carbon、Acta Biomaterialia、Acta Materialia、Scripta Materialia、Applied Physics Letters、金属学报等国内外学术刊物上发表论文100余篇(其中SCI收录90篇, Web of Science 检索他引次数2000余次，h-index 27)，出版英文章节著作一部，获授权发明专利11项。部分成果获2015年教育部自然科学奖一等奖（排名2）、全国优秀博士论文提名奖(2005年)。2012入选“2010-2011年度苏州市高等院校、科研院所紧缺高层次人才引进资助计划”；2010年入选江苏省第七批“六大人才高峰行动计划”。

目前为国家自然科学科学奖、国家自然科学基金、北京市自然科学基金、浙江省自然科学基金、湖南省自然科学基金等项目评审专家，并为Acta Biomaterialia、Carbon、Applied Physics Letters、Scientific Report等20余家学术刊物审稿人。

代表性论文：

1.  Ying Song, Wiewei Liu, Yufeng Sun, Shaokang Guan, Yao Chen*. Microstructural evolution and mechanical properties of graphene oxide reinforced Ti6Al4V matrix composites fabricated using spark plasma sintering. Nanomaterials, 2021;11:1440. (SCI IF 4.324)

2. Yao Chen*, Jia Ren, Yufeng Sun, Weiwei Liu, Dong Zhao, Xiaolong Lu, Shaokang Guan. Efficacy of graphene nanosheets on the plasma sprayed hydroxyapatite coating: improved strength, toughness and in-vitro bioperformance with osteoblast.Materials & Design, 2021;203:109585. (SCI IF 6.289)

3. X.L. Lu, T. Dolmetsch, C. Zhang, Y. Chen, B. Bosel, A. Arvind. In-situ Synthesis of Boron Nitride Nanotube Reinforced Aluminum Oxide Composites by Molecular Mixing. Ceramics International. 2021;47(5):13970-13979. (SCI IF 3.830)

4. Yao Chen*, Ying Song, Guangyu He, Yufeng Sun, Weiwei Liu, Shaokang Guan. BN nanosheet reinforced Ni₃Al compositewith improved tribological behavior under isooctane-lubricated sliding condition.Intermetallics, 2020;126:106936. (SCI IF=3.398)

5. Yao Chen*, Jia Ren, Weiwei Liu, Dong Zhao. Enhanced scratch performance of plasma sprayed hydroxyapatite composite coatings reinforced with BN nanoplatelets. Coatings, 2020;10:652. (SCI IF=2.436)

6. Xiaolong Lu, Pranjal Nautiyal, Jenniffer Bustillos, Archana Loganathan, Cheng Zhang, Yao Chen, Benjamin Boesl, Arvind Agarwal. Hydroxylated boron nitride nanotube-reinforced polyvinyl alcohol nanocomposite films with simultaneous improvement of mechanical and thermal properties. Polymer Composites, 2020;41(12)5182-5194. (SCI IF=2.256)

7. Y.F. Sun, Y. Chen, N. Tsuji, S.K. Guan. Microstructure evolution and mechanical properties of nanostructured Cu/Ni multilayer fabricated by accumulative roll bonding. Journal of Alloys and Compounds, 2020;819:152956. (SCI IF=4.650)

8.  Jia Ren, Dong Zhao, Fei Qi, Weiwei Liu, Yao Chen*. Heat and hydrothermal treatments on the microstructure evolution and mechanical properties of plasma sprayed hydroxyapatite coatings reinforced with graphene nanoplatelets. Journal of the Mechanical Behavior of Biomedical Materials. 2020;101:103418. (SCI IF=3.485)

9.  Xiaolong Lu, SadhanaBhusal, Guangyu He,DongZhao,ChengZhang, Arvind Agarwal, Yao Chen*. Efficacy of graphene nanoplateletson splat morphology and microstructure of plasma sprayed alumina coatings. Surface & Coatings Technology, 2019;365:54-61. (SCI IF=3.784)

10. Ying Song, Guangyu He, Yongguang Wang, Yao Chen*. Tribological behavior of boron nitride nanoplatelet reinforced Ni₃Al intermetallic matrix composite fabricated by selective laser melting. Materials & Design, 2019;165:107579. (SCI IF 6.289)

11. Jiaying Zhu, Jia Ren, Yao Chen*. Splat-boundary reinforcement induced by graphene in plasma sprayed hydroxyapatite composite coating. Carbon Letters, 2019;29:31-35.(SCI IF 1.992)

12. Z.W. Xing, W.W. Liu, Y. Chen, W.L. Li. Effect of plasticizer on the fabrication and properties of alumina ceramic by stereolithography-based additive manufacturing. Ceramics International,2018;44(16)：19939-44. (SCI IF 3.830)

13. Y.G. Wang, Y. Chen, D. Zhao, X.L. Lu, W.W. Liu, F. Qi. Deformation mechanism of CrN/nitriding coated steel in wear and nano-scratch experiments under heavy loading conditions. Applied Surface Science, 2018;447:100-106. (SCI IF=6.182)

14. Jiaying Zhu, Yao Chen*, Jia Ren, Dong Zhao, Weiwei Liu. Boron nitride nanoplatelets induced synergetic strengthening and toughening effects on splats and their boundaries of plasma sprayed hydroxyapatite coatings. Ceramics International, 2018;44:10604-10. (SCI IF 3.830)

15. Yao Chen*, Dong Zhao, Fei Qi, Weiwei Liu. Scratch behavior of boron nitride nanotube/boron nitride nanoplatelet hybrid reinforced ZrB₂-SiC composites. Ceramics International, 2018;44:3277-3281. (SCI IF 3.830)

16. Jia Ren, Yao Chen*, Xiaogang Zhang. Graphene accelerates osteoblast attachment and biomineralization. Carbon Letters, 2017,22:42-7. (SCI IF 1.992)

17. Jianan Su, Yao Chen^*, Qiqi Huang, Graphene nanosheet-induced toughening of yttria-stabilized zirconia. Applied Physics A, 2017,123(1):1-11. (SCI IF 1.857)

18. Y.J. Zhai, X.B. Liu, S.J. Qiao, M.D. Wang, X.L. Lu, Y.G. Wang, Y. Chen, L.Y. Ying. Characteristics of laser clad α-Ti/TiC+(Ti,W)C_1−x/Ti₂SC+TiS composite coatings on TA2 titanium alloy. Optics & Laser Technology, 2017, 89:97-107. (SCI IF=3.233)

19. Y. Song, Y. Chen*, W.W, Liu, W.L. Li, Y.G. Wang, X.B. Liu. Microscopic mechanical properties of titanium composites containing multi-layer graphene nanofillers. Materials & Design, 2016;109:256-263. (SCI IF 6.289)

20. X.L. Lu, X.B. Liu, B.C. Yu, G.Y. Fu, G.X. Zhu, Y.G. Wang, Y. Chen. Effects of annealing on laser clad Ti₂SC/CrS self-lubricating anti-wear composite coatings on Ti6Al4V alloy: Microstructure and tribology. Tribology International, 2016;101:356-363. (SCI IF=4.271)

21. X.L. Lu, X.B. Liu, P.C. Yu, Y.J. Zhai, S.J. Qiao, M.D. Wang, Y. Chen. Effects of heat treatment on microstructure and mechanical properties of Ni60/h-BN self-lubricating anti-wear composite coatings on 304 stainless steel by laser cladding. Applied Surface Science,2015;355:350-358. (SCI IF=6.182)

22. Q.Q. Huang, Y. Song, W.W. Liu, Y. Chen*, F. Qi, D. Zhao, Y.G. Wang. Spherical indentation with multiple partial unloading for assessing the mechanical properties of ZrB₂–SiC composites. Ceramics International, 2015;41:12349-12354. (SCI IF=3.830)

23. 刘卫卫，张律，岳春光，苏佳楠，白朴存，陈瑶*. (BNNT-BNNP)/(ZrB₂-SiC)超高温陶瓷复合材料形变强化及机理. 稀有金属材料与工程，2014;43(12):3078-3081. (SCI IF=0.485)

24. Y. Chen*, Weiwei Liu, Fei Qi. Developed Numerical Investigation into Residual Stress by Vickers Instrumented Indentation Technique.Applied Mechanics & Materials, 2015 , 719-720 :38-45.

25. L. Zhang, X.G. Zhang, Y. Chen*, J.N. Su, W.W. Liu, T.H. Zhang, F. Qi, and Y.G. Wang. Interfacial stress transfer in a graphene nanosheet toughened hydroxyapatite composite. Applied Physics Letters, 2014, 105(16),161908. (SCI IF=3.597)

26. Z.F. Xiang, X.B. Liu, J. Ren, J. Luo, S.H. Shi, Y. Chen, G.L. Shi, S.H. Wu. Investigation of laser cladding high temperature anti-wear composite coatings on Ti6Al4V alloy with the addition of self-lubricant CaF₂. Applied Surface Science, 2014;313:243-250. (SCI IF=6.182)

27. Lv Zhang，Weiwei Liu, Yao Chen*. Mechanical properties and toughening mechanisms of multi-walled carbon nanotube reinforced yttria-stabilized zirconia composites. Advanced Materials Research, 2014,1052:24-27.

28. L. Zhang, W.W. Liu, C.G. Yue, T.H. Zhang, P. Li, Z.W. Xing，Y. Chen*. A tough graphene nanosheet/hydroxyapatite composite with improved in vitro biocompatibility. Carbon, 2013;61:105-115. (SCI IF=8.821) 该论文入选扩展ESI高被引用论文

29. C.G. Yue, W.W. Liu, L. Zhang, T.H. Zhang, Y. Chen*. Fracture toughness and toughening mechanisms in (ZrB₂-SiC) composite reinforced with boron nitride nanotubes and boron nitride nanoplatelets. Scripta Materialia. 2013;68(8), 579-582. (SCI IF=5.079)

30. Y. Chen*, K. Balani, A. Agarwal. Do thermal residual stresses contribute to the improved fracture toughness of carbon nanotube/alumina nanocomposites? Scripta Materialia, 2012;66(6),347-350. (SCI IF=5.079)

31. Y. Chen*, A. Kobayashi, Bimodal Microstructural Samarium Doped Ceria with and without Carbon Nanotubes Fabricated through Plasma Spray. Transactions of JWRI, 2010;39(1):57-60.

32. Yao Chen*, Srinivasa R. Bakshi, Arvind Agarwal. Correlation between nanoindentation and nanoscratch properties of carbon nanotube reinforced aluminum composite coatings. Surface & Coating Technique, 2010;204(16-17):2709-2715. (SCI IF=3.784)

33. Srinivasa R. Bakshi, Di, Wang, Timothy Price, Deen Zhang, Anup K. Keshri, Yao Chen, D. Graham McCartney, Phil Shipway, Arvind Agarwal. Microstructure and wear properties of aluminum/aluminum-silicon composite coatings prepared by cold spraying. Surface & Coating Technique, 2009;204(3):503-510. (SCI IF=3.784)

34. V. Pasumarthi, Y. Chen, S.R. Bakshi and A. Agarwal. Reaction synthesis of Ti₃SiC₂ phase in the plasma sprayed coating. Journal of Alloys and Compounds,2009;484(1-2):113-117. (SCI IF=4.650)

35. A. K. Keshri, S. R. Bakshi, Y. Chen, T. Laha, X. Li, C. Levy, A. Agarwal. Nanomechanical Behavior of Plasma Sprayed PZT Coating. Surface Engineering, 2009;25(4): 270-275(6).(SCI IF=2.433)

36. T. Laha, Y. Chen, A. Agarwal.Tensile Properties of Carbon Nanotube Reinforced Aluminum Nanocomposite Fabricated by Plasma Spray Forming. Composites Part A, 2009;40(5):589-594.

37. Y. Chen, S. Omar, A. K. Keshri, K. Balani, K. Babu, J. C. Nino, S.Seal, A. Agarwal. Ionic Conductivity of Plasma Sprayed Nanocrystalline YSZ Electrolyte. Scripta Materialia,2009;61(11):1023-1026. (SCI IF=5.079)

38. Y. Chen, S. R. Bakshi and A. Agarwal, Inter-Splat Friction Force and Splat Sliding in Plasma Sprayed Aluminum Alloy Coating During Nanoindentation and Microindentation, ACS Applied Materials & Interfaces, 2009; 1(2): 235-238. (SCI IF=8.758)

39. Y. Chen, K. Balani, Narendra B. Dahotre, A. Agarwal. Laser Remelting of Plasma- sprayed Alumina Matrix Composite Coatings Reinforced by Carbon Nanotubes. Applied Physics A, 2009; 94(4):861-870. (SCI IF=1.784)

40. K. Balani, S. Harmikar, A. K. Keshri, Y. Chen, N. B. Dahotre, A. Agarwal. Multiscale wear of plasma sprayed carbon nanotube reinforced aluminum oxide nanocrystalline coating. Acta Materialia, 2008; 56(20) 5984-5994. (SCI IF=7.656)

41. Y. Chen, T. Laha, K. Balani and A. Agarwal. Nanomechanical properties of hafnium nitride coating. Scripta Materialia, 2008;58(12):1121-4. (SCI IF=5.079)

42. Y. Chen, K. Balani, A. Agarwal. Analytical model on interfacial shear stress of carbon nanotube reinforced aluminum oxide composites. Applied Physics Letters, 2008; 92: 011916. (SCI IF=3.597)

43. Y. Chen, K. Balani, A. Agarwal. Modified Eshelby Tensor Modeling for Elastic Property Prediction of Carbon Nanotube Reinforced Composites. Applied Physics Letters, 2007; 91: 013903. (SCI IF=3.597)

44. K. Balani, Y. Chen, S. P. Harimkar, N.B. Dahotre, A. Agarwal. Tribological Behavior of Plasma Sprayed HA Composite Coating Reinforced with Carbon Nanotubes. Acta Biomaterialia, 2007; 3 (6): 944-51. (SCI IF=7.242)

45. Y. Chen*, T.H. Zhang, C.H. Gan, G. Yu. Wear studies of hydroxyapatite composite coating reinforced by carbon nanotubes. Carbon, 2007; 45: 998-1004. (SCI IF=8.821)

46. Y. Chen*, H.M. Wang. Growth morphologies and mechanisms of MC carbide under non-equilibrium solidification conditions. Journal of Materials Research, 2006;21:375-379. (SCI IF=2.502)

47. Y. Chen, H.M. Wang. Microstructure and wear resistance of laser melted TiC reinforced nickel aluminide dual-phase matrix in situ composites. Intermetallics, 2006;14(3):325-331. (SCI IF=3.398)

48. Y. Chen*, Y.Q. Zhang, C.H. Gan, C.Y. Zheng, G. Yu. Carbon nanotube reinforced hydroxyapatite composite coatings produced through laser surface alloying.Carbon, 2006;44(1):37-45. (SCI IF=8.821) 该论文入选Carbon杂志2006-2010年中国大陆50篇高被引用论文。

49. Y. Chen*, C.H. Gan, T.H. Zhang, G. Yu, P.C. Bai, A. Kaplon. Laser surface alloyed carbon-nanotube reinforced hydroxyapatite composite coatings. Applied Physics Letters, 2005; 86: Article No.251905. (SCI IF=3.597)

50. Y. Chen, H.M. Wang. Laser melted TiC reinforced nickel aluminide matrix in situ composites.Journal of Alloys and Compounds, 2005;391:49-54. (SCI IF=4.650)

51. Y. Chen, C.H. Gan, L.X. Wang, G. Yu, A. Kaplon. Laser surface modified ductile iron by pulsed laser beam with two-dimensional array distribution. Applied Surface Science, 2005;245:316-321. (SCI IF=6.182)

52. Y. Chen, H.M. Wang. Eutectic MC carbide growth morphologies of a laser clad TiC/FeAl composite coating. Materials Letters, 2005;59(28):3699-3702. (SCI IF=3.204)

53. Y. Chen, H.M. Wang. Rapidly solidified MC carbide morphologies of a pulsed laser surface alloyed with γ-TiAl intermetallics with carbon. Scripta Materialia, 2004;50:507-510. (SCI IF=5.079)

54. Y. Chen, H.M. Wang. High-temperature wear resistance of a laser clad TiC reinforced FeAl intermetallic matrix in situ composite coating. Surface & Coatings Technology,2004;179: 252-256. (SCI IF=3.784)

55. Y. Chen, H.M. Wang. Microstructure and wear resistance of a laser clad TiC reinforced nickel aluminides matrix composite coating. Materials Science and Engineering A, 2004;368:80-87. (SCI IF=4.6521)

56. Y. Chen, H.M. Wang. Microstructure and wear resistance of laser clad TiC reinforced FeAl intermetallic matrix composite coating.Surface & Coatings Technology,2003; 168:30-36. (SCI IF=3. 784)

57. Y. Chen, H.M. Wang. Microstructure and high-temperature wear resistance of a laser surface alloyed γ-TiAl with carbon. Applied Surface Science, 2003;220: 186-192. (SCI IF=6.182)

58. Y. Chen, H.M. Wang. Growth morphology and mechanism of TiC carbide in the laser surface alloying coating on the substrate of TiAl intermetallics. Journal of Alloys and Compounds, 2003; 351: 304-308. (SCI IF=4.650)

59. Y. Chen, H.M. Wang. Growth morphology and mechanism of primary TiC in laser clad TiC/FeAl composite coating. Materials Letters, 2003:57: 1233-1238. (SCI IF=3.204)

60. Y. Chen, H.M. Wang. Microstructure of laser clad TiC/NiAl-Ni₃(Al,Ti,C) wear resistant intermetallic matrix composite coating. Materials Letters, 2003;57: 2029-2036. (SCI IF=3.204)

获奖情况：

2015年获教育部“高等学校自然科学奖”一等奖（关键摩擦副机械零部件激光熔覆特种耐磨涂层及磨损特性研究，第二获奖人）；

2012入选“2010-2011年度苏州市高等院校、科研院所紧缺高层次人才引进资助计划”；

2010年入选江苏省第七批“六大人才高峰行动计划”；

2008年获日本科学振兴会(JSPS)“外国人特别研究员”(P0878)；

2007年获美国自然科学基金委员会“NSF Fellowship Award for Inspiring the Coalesence of Fundamental and Application Specific Functional Nanomaterial Development”；

2006年获“全国优秀博士论文提名奖”

在研项目

装备预研国防基金等项目

需 求

联系方式

chenyao@suda.edu.cn