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姓  名 沈同德 性  别
民  族 汉族 出 生 年 月
政 治 面 貌
现 有 职 称 教授
最 高 学 历 博士研究生 所 属 单 位 亚稳材料制备技术与科学国家重点实验室
导 师 身 份 博士生导师 毕 业 院 校 中国科学院金属研究所
Email tdshen@ysu.edu.cn 地   址 中国、河北、秦皇岛、河北大街西段438号(西校区)
更 新 时 间 2017-03-29 11:00:30 邮   编 066004
人 生 格 言
个人简历
1982-1986   浙江大学、金属材料科学与工程专业                 学士学位    
    1988-1991   中国科学院金属研究所、金属材料及热处理专业       硕士学位    
    1991-1993   中国科学院金属研究所、金属材料及热处理专业       博士研究生    
    1993-1995   美国北卡罗来那州立大学、材料科学与工程学系       合培博士    
    1995-1998   美国洛斯阿拉莫斯国家实验室、材料科学与技术部     博士后    
    1998-2000   美国洛斯阿拉莫斯国家实验室、材料科学与技术部     研究员    
    2000-2008   美国洛斯阿拉莫斯国家实验室、材料科学与技术部     终身研究员    
    2009-2012   南京工业大学、材料化学工程国家重点实验室         教授    
    2013-今     燕山大学、亚稳材料制备技术与科学国家重点实验室   教授    
社会兼职

国际学术杂志评审专家:
     Acta Materialia
     Applied Physics Letters
     International Journal of Modern Physics B
     Journal of Alloys and Compounds
     Journal of Applied Physics
     Journal of Chemical Physics
     Journal of Magnetism and Magnetic Materials
     Journal of Manufacturing Processes
     Journal of Materials Research
     Journal of Materials Science
     Journal of Non-Crystalline Solids
     Journal of Physics and Chemistry of Solids
     Journal of Solid State Chemistry
     Materials Science and Engineering A
     Materials Research Bulletin
     Metallurgical and Materials Transactions
     Modern Physics Letters B
     Physica B
     Physical Review B
     Scripta Materialia
     Scientific Reports   


 

 国际学术会议分会主席:
     TMS 2007: Mechanical Behavior of Nanostructured Materials
     TMS 2008: Particle Beam-Induced Radiation Effects in Materials: Nanostructures
     TMS 2008/5th International Symposium on Ultra-Fine Grained Materials
     International Symposium of Amorphous Alloys (Nov. 19-22, 2008, Hangzhou,China)
     International Conference on Mechanical Properties of Materials (May 24-28, 2010,  Hangzhou, China)
     IUMRS-ICAM2013 International Conference on Advanced Materials (September 22-28, 2013, Qingdao, China)  
     2nd International symposium on Metastable Materials Science & Technology, Qinhuangdao, China, Oct. 12-16, 2015.
     IUMRS-ICA 2016 Symposium G: Amorphous and High-entropy Alloys, Qingdao, China, Oct. 20-24, 2016.
     2017 TMS Annual Meeting & Exhibition, Mechanical Behavior of Nanostructured Materials,San Diego, California, USA, Feb. 26 – March 2, 2017   


 

 科学研究基金和项目评审专家:
      City University of Hong Kong – Strategic Research Grant (SRG)
      Louisiana State University – Research Competitiveness Subprogram (RCS)
      Department of Energy (DOE) – Basic Energy Sciences (BES) research
      教育部“长江学者奖励计划”(海外评审专家)
      国家重点基础研究发展计划(973计划)   

研究领域

纳米材料的制备、结构、磁性与力学性能
非晶材料的制备、结构与磁性
抗辐照纳米材料
锂离子电池纳米电极材料
超硬材料
高熵合金

教学科研信息

发表论文:


(*: ISI SciSearch Publications, #: ISI Proceedings Publications)(Citations: 3724, h-index: 31 (Google Scholar))  


 

1*. T. D. Shen, K. Y. Wang, M. X. Quan and J. T. Wang, “Displacement  reaction of Fe and CuO induced by mechanical alloying”, Scripta Metallurgica et Materialia, 25 (1991) 2143-2146.

2*. K. Y. Wang, T. D. Shen, J. T. Wang and M. X. Quan, “Amorphization reaction during mechanical alloying: influences of the milling atmospheres”, Scripta Metallurgica et Materialia, 25 (1991) 2227-2231.

3*. K. Y. Wang, A. Q. He, T. D. Shen, M. X. Quan and J. T. Wang, “Investigations of the amorphization reaction by amorphous phase through the mechanical milling”, Journal of Applied Physics, 70 (1991) 7158-7160.

4*. T. D. Shen, K. Y. Wang, J. T. Wang and M. X. Quan, “The influence of ball-milling condition on the kinetics of mechanical alloying”, Proceedings of the 6th National Conference on Amorphous Materials and Physics (in Chinese) (Nov. 11-18, 1991,  Guilin, China),  p. 238-239.

5.  T. D. Shen, M. X. Quan and J. T. Wang, “The study on the mechanism of formation of bulk amorphous materials”, ibid, p. 236-237.

6.  T. D. Shen, K. Y. Wang, J. T. Wang and M. X. Quan, “Amorphization transition  induced by mechanical alloying of alloy system without chemical driving force”, ibid., p. 232-233.

7.  T. D. Shen, J. T. Wang and M. X. Quan, “Amorphization transition in Ni-Ti system studied by DSC”, ibid. p. 234-235.

8.  K. Y. Wang, J. T. Wang, T. D. Shen and M. X. Quan, “Solid state reaction between pure Ni and amorphous Fe78Si12B10 alloys”, ibid., p. 228-229.

9#. T. D. Shen, K. Y. Wang, M. X. Quan and J. T. Wang, “Amorphous phase formation in the Fe-W system induced by mechanical alloying”, Materials Science Forum, 88-90 (1992) 391-397.

10*. T. D. Shen, K. Y. Wang, M. X. Quan, J. T. Wang, and W. D. Wei,  “Preparation and  reactivities of composite nanocrystalline solids through mechanical alloying”, Journal of Non-Crystalline Solids, 15 (1992) 468-471.

11*. T. D. Shen, K. Y. Wang, J. T. Wang and M. X. Quan, “Solid state displacement reaction of Fe and CuO induced by mechanical alloying”, Materials Science and Engineering, A151 (1992) 189-195.

12*. T. D. Shen, J. T. Wang, M. X. Quan and W. D. Wei, “Amorphization induced by mechanical alloying and cold-rolling”, Journal of Non-Crystalline Solids, 150 (1992) 464-467.

13*. T. D. Shen, K. Y. Wang, M. X. Quan and J. T. Wang, “Amorphous phase transition mechanism by the mechanical alloying of the Fe-W system”, Journal of Applied Physics, 71 (1992) 1967-1971.

14*. T. D. Shen, K. Y. Wang, M. X. Quan and J. T. Wang, “Formation of  nanocrystalline Fe/SiC composites by mechanical alloying”, Journal of Materials Science Letters, 11 (1992) 1576-1578.

15*. K. Y. Wang, T. D. Shen, M. X. Quan and J. T. Wang, “Different transition paths of  the amorphization by mechanical alloying”, Journal of Materials Science Letters,  11 (1992) 129-131.

16*. K. Y. Wang, T. D. Shen, J. T. Wang and M. X. Quan, “Influences of atmospheres on the amorphization by mechanical alloying Ni-Ti system”, Journal of Non-Crystalline Solids, 150 (1992) 456-459.

17*. K. Y. Wang, T. D. Shen, M. X. Quan and J. T. Wang, “Self-sustaining reaction during mechanical alloying Ni60Ti40 in oxygen atmosphere”, Scripta Metallurgica et Materialia, 26 (1992) 933-937.

18*. K. Y. Wang, T. D. Shen, J. T. Wang and M. X. Quan, “Effects of atmospheres on further milling the mechanically-alloyed Ni60Ti40 amorphous powders”, Journal of Materials Science Letters, 11 (1992) 1170-1172.

19*. T. D. Shen, M. X. Quan and J. T. Wang, “Solid state amorphization reactions in Ni/Ti  multilayer composites prepared by cold rolling”, Journal of Materials Science, 28 (1993) 394-398.

20*. T. D. Shen, Y. L. Wu, M. X.. Quan, J. T. Wang and Z. Q. Hu, “Calculation of temperature for the formation of competing intermetallic compounds in Ni/Ti multilayers”, Materials Letters, 17 (1993) 258-262.

21*. T. D. Shen, M. X. Quan and Z. Q. Hu, “Formation of amorphous Ge-S semiconductor alloy by mechanical alloying”, Applied Physics Letters, 63 (1993) 1637-1639.

22.  J. T. Wang and T. D. Shen, “Study and progress of mechanical alloying”, Physics (in   Chinese), 22(8)  (1993) 456-460.

23.  T. D. Shen, M. X. Quan and J. T. Wang, “New materials(I): amorphous, quasicrystalline and nanocrystalline solids by mechanical alloying”,  Materials Science & Engineering (in Chinese), 11(2) (1993) 21-26.

24.  T. D. Shen, M. X. Quan and J. T. Wang, “New materials(II):  dispersion strengthened alloy, magnetic material, superconducting phase, intermetallic compounds and mechanochemical effect by mechanical alloying”,  Materials  Science& Engineering  (in Chinese), 11(3) (1993) 17-22.

25*. K. Y. Wang, T. D. Shen, J. T. Wang and M. X. Quan, “Characteristics of the mechanically-alloyed Ni60Ti40amorphous powders during mechanical alloying in different atmospheres”, Journal of Materials Science, 28 (1993) 6474-6478.

26*. K. Y. Wang, T. D. Shen, M. X. Quan, W. D. Wei, “Hall-Petch relationship in nanocrystalline titanium produced by ball-milling”, Journal of Materials Science Letters, 12 (1993) 1818-1820.

27*. M. X. Quan, K. Y. Wang, T. D. Shen, and J. T. Wang, “Solid state amorphization  transformations  induced by mechanical alloying”, Journal of Alloy and Compounds, 194 (1993) 325-330.

28#. W. L. Gao, T. D. Shen, Z. G. Liu, H. G. Jiang, and M. X. Quan,  “Solid state amorphization between elemental Al and amorphous Ni70Zr30 by mechanical milling”, Transactions of the Materials Research Society of Japan, 16  (1994) 101-104.

29#. T. D. Shen, K. Y. Wang, M. X. Quan, H. G. Jiang, and Z. Q. Hu, “Synthesis and characteristics of amorphous Ge-S semiconductor alloys by mechanical alloying”, Transactions of the Materials Research Society of Japan, 16  (1994) 55-58.

30*. T. D. Shen, M. X. Quan, J. T. Wang and Z. Q. Hu, “Amorphous phase growth by  isothermal-annealing-induced interdiffusion reactions in mechanically deformed Ni/Ti multilayers”, Journal of Materials Science, 29 (1994) 2981-2986.

31*. K. Y. Wang, T. D. Shen, H. G. Jiang, M. X. Quan and W. D. Wei, “Structural evolutions of Ni-Ti systems caused by mechanical alloying in different atmospheres”, Materials Science and  Engineering, A179/180 (1994) 215-219.

32*. K. Y. Wang, A. Q. He, T. D. Shen, M. X. Quan and J. T. Wang, “Synthesis of Al-based metastable alloys by mechanical milling Al and amorphous Fe78Si12B10 powders”, Journal of Materials  Research, 9 (1994) 866-874.

33*. Y. Guo, Z. F. Gong, H. D. Mo, S. X. Wang, B. Z. Yang, T. J. Wu, Z. H. Bian, X. W. Tang, C. S. Xiong, J. S. Zhu, J. Y. Xiao, T. D. Shen, M. X. Quan, J. T. Wang, “The structure and Compton profile of  nanocrystalline graphite produced by mill grinding”, Physics Letters, A193 (1994) 298-304.

34#. C. C. Koch, T. D. Shen, T. Malow and O. Spaldon, “Mechanical hardness as a probe of nanocrystalline materials”, in “Grain Size and Mechanical Properties-Fundamentals and  Applications” (Materials Research Society Symposium Proceedings, vol. 362, 1995), p.253-264.

35#. T. D. Shen and C. C. Koch, “The influence of dislocation structure on formation of nanocrystals by mechanical attrition”, Materials Science Forum, 179-181 (1995)17-24.

36*. T. D. Shen, C. C. Koch, T. L. McCormick, R. J. Nemanich, J. Y. Huang and J. G. Huang, “On the Structure and property characteristics of amorphous/nanocrystalline silicon produced by ball milling”,  Journal of Material Research, 10 (1995) 139-148.

37*. T. D. Shen, C. C. Koch, T. Y. Tsui and G. M. Pharr, “On the elastic modulus of nanocrystalline Cu, Ni and their alloys prepared by mechanical milling/alloying”, Journal of Materials  Research, 10 (1995) 2892-2896.

38*. T. D. Shen and C. C. Koch, “Formation and hardening effects in nanocrystalline Ti-N alloys prepared by mechanical alloying”,  NanoStructured Materials, 5 (1995) 615-629.

39*. T. D. Shen and C. C. Koch, “Formation, solid solution hardening and softening of nanocrystalline solid solutions prepared by mechanical attrition”, Acta Metallurgica  et Materialia, 44 (1996) 753-761.

40*.  T. D. Shen, W. Q. Ge, K. Y. Wang, M. X. Quan, J. T. Wang, W. D. Wei, and C. C. Koch, “Structural disorder in nanocrystalline graphite through ball milling”,  NanoStructured Materials, 7 (1996) 393-399.

41*. G. Le Caër,  P. Delcroix, T. D. Shen, and B. Malaman, “Mössbauer  investigation of intermixing during ball milling of Fe0.3Cr0.7 and Fe0.5W0.5 powder mixtures”,  Physical Review  B, 54 (1996-II) 12775-12786.

42#. C. C. Koch and T. D. Shen, “Solid solution hardening/softening in nanocrystalline alloys”,  Processing and properties of nanocrystalline materials (edited by C. Suryanarayana, J. Singh,  and F. H. Froes (Minerals, Metals, & Materials Society, Warrendale, PA, 1996), pp.333-343.

43.  R. Gao, K. Shi, Z. Wang, and T. Shen, “Preparation of nanocrystalline titania”, Acta Metallurgica Sinica, 32 (1996) 1097-1101.

44*. T. D. Shen, C. C. Koch, K. Y. Wang, M. X. Quan, and J. T. Wang,  “Solid state reaction in  nanocrystalline Fe/SiC composites”, Journal of  Materials Science, 32 (1997) 3835-3839.

45*. C. C. Koch, T. D. Shen, and Y. Fahmy, “Microstructural and structural changes in Si and C induced by mechanical attrition”, Materials Science Forum,  235-238 (1997) 487-496.

46*. T. D. Shen, I. Shmagin, C. C. Koch, R. M. Kolbas, Y. Fahmy, L. Bergman, R. J. Nemanich,  M. T. McClure, Z. Sitar and M. X. Quan, “Photoluminescence from mechanically milled Si and SiO2 powders”,  Physical Review B,  55 (1997-II) 7615-7623.

47#. W. L. Zhang, A. Visintin, S. Srinivasan, T. D. Shen, and R. B. Schwarz, “Zn additive by mechanical alloying for metal hydride electrodes”, Electrochemical Society Series, 96 (16) (1997) 227-238.

48*. R. B. Schwarz, C. J. Wetteland,  T. D. Shen, E. Ustundag, and K. E. Sickafus,  “Vanadium-Spinel composites for structure applications in hostile environments”, Materials Science and Engineering, A234-236 (1997) 1091-1094.

49*. Y. He, T. D. Shen, and R. B. Schwarz, “Bulk amorphous metallic alloys: synthesis by fluxing techniques and properties”, Metall. Mater. Trans. A, 29 (1998) 1795-1804.

50#. T. D. Shen, R. B. Schwarz, E. Üstündag and K. E. Sickafus, "V/MgAl2O4 composites for hostile environment applications-Part I: processing", Ceramic Engineering and Science Proceedings, Vol. 19, Issues 3-4, pp. 155-162, 1998.

51#. E. Üstündag, K. E. Sickafus, C. Wetteland, T. D. Shen and R. B. Schwarz, "V/MgAl2O4 composites for hostile environment applications-Part II: properties’’, Ceramic Engineering and Science Proceeding, Vol. 19, Issues 3-4, pp. 163-170, 1998.

52*. T. D. Shen, Y. He, and R. B. Schwarz, “Bulk amorphous Pd-Ni-Fe-P alloys: Preparation and characterization”, Journal of Materials Research, 14 (1999) 2107-2115.

53*. T. D. Shen, R. B. Schwarz, and J. D. Thompson, “Paramagnetism, superparamagnetism and spin glass behavior in bulk amorphous Pd-Ni-Fe-P alloys”, Journal of Applied Physics, 85 (1999) 4110-4119.

54*. Y. Fahmy, T. D. Shen, D. Tucker, R. J. Spontak, and C. C. Koch, “Possible  evidence of the stabilization of beta-carbon nitride by high energy ball milling”, Journal of Materials Research, 14 (1999) 2488-2499

55*. T. D. Shen and R. B. Schwarz, “Bulk ferromagnetic glasses prepared by flux melting and water quenching”,   Applied Physics Letters, 75 (1999) 49-51.

56*. T. D. Shen and R. B. Schwarz, “Bulk ferromagnetic glasses in the Fe-Ni-P-B system”, Acta Materialia, 49 (2001) 837-847.

57*. T. D. Shen, U. Harms, and R. B. Schwarz, “Bulk Fe-based metallic glasses with extremely soft ferromagnetic properties”,  Materials Science Forum, 386-388 (2002) 441-446.

58*. T. D. Shen, R. B. Schwarz, J. Y. Coulter,  and J. D. Thompson, “Magnetocaloric effect in bulk amorphous Pd40Ni22.5Fe17.5P20 alloy”, Journal of Applied Physics, 91 (2002) 5240-5245.

59*. M. K. Miller, T. D. Shen, and R. B. Schwarz, “Atom probe tomography study of the decomposition of a bulk metallic glass”, Intermetallics, 10 (2002) 1047-1052.

60*. Y. Zhao, D. W. He, L. L. Daemen, T. D. Shen, R. B. Schwarz, Y. Zhu, D. L. Bish, J. Huang, J. Zhang, G. Shen, J. Qian, and T. W. Zerda, “Superhard B-C-N materials synthesized in nanostrucutred bulks”, Journal of Materials Research, 17 (2002) 3139-3145.

61*. U. Harms,   T. D. Shen,  and R. B. Schwarz, “ Thermal conductivity of Pd40Ni40-xCuxP20 metallic glasses”,  Scripta Materialia, 47 (2002) 411-414.

62*. D. W. He, Y. S. Zhao, L. Daemen, J. Qian, T. D. Shen, and T. W. Zerda, “Boron suboxide: As hard as cubic boron nitride ”,  Applied Physics Letters, 81 (2002) 643-645.

63#. R. B. Schwarz and T. D. Shen, “High-strength, high-conductivity bulk nanostructrued Ag-Cu alloys”, Processing and properties of structural nanomaterials, edited by L. L. Shaw, C. Suryanarayana, and R. S. Mishra (Minerals, Metals, & Materials Society, Warrendale, PA, 2003), pp.141-147.

64*. M. K. Miller, T. D. Shen, and R. B. Schwarz, “Atom probe studies of metallic glasses”,  Journal of Non-crystalline Solids, 317 (2003) 10-16.

65*. X. Zhang, A. Misra, H. Wang, T. D. Shen, J. G. Swadener, J. D. Embury, H. Kung, R. G. Hoagland, and M. Nastasi, “Strengthening mechanisms in nanostructured copper/304 stainless steel multilayers”, Journal of Materials Research, 18 (2003) 1600-1606.

66*. U. Harms, R. B. Schwarz, and T. D. Shen, “Crystallization kinetics in small volumes of undercooled liquid”, Philosophical Magazine Letters, 83 (2003) 503-509.

67*. T. D. Shen, U. Harms, and R. B. Schwarz, “Correlation between the volume changes during crystallization and the thermal stability of supercooled liquids”, Applied Physics Letters, 83 (2003) 4512-4514.

68*. D. W. He, Y. S. Zhao, T. D. Shen, R. B. Schwarz, J. Qian, K. A. Lokshin, S. Bobev, L. L. Daemen, H. K. Mao, J. Z. Hu, J. Shu, and J. Xu, “Bulk metallic glass gasket for high pressure, in situ x-ray diffraction”, Review of Scientific Instruments, 74 (2003) 3012-3016.

69*. X. Zhang, A. Misra, H. Wang, T. D. Shen, M. Nastasi, T. E. Mitchell, J. P. Hirth, R. G. Hoagland, and J. D. Embury, “Enhanced hardening in Cu/330 stainless steel multilayers by nanoscale twinning”, Acta Materialia, 52 (2004) 995-1002.

70*. D. W. He, Y. S. Zhao, L. L. Daemen, J. Qian, K. Lokshin, T. D. Shen, J. Zhang, and A. C. Lawson, “Thermoelastic and texture behavior of aluminum at high pressure and high temperature investigated by in situ neutron diffraction”, Journal of Applied Physics, 95 (2004) 4645-4650.

71*. Z. Wang, Y. Zhao, K. Tait, Z. Liao, D. Schiferl, C. Zha, R. T. Downs, J. Qian, Y. Zhu, and T. Shen, “A quenchable superhard carbon phase synthesized by cold compression of carbon nanotubes”, Proceedings of the National Academy of Sciences of the United States of America, 101 (2004) 13699-13702.

72*. R. B. Schwarz, T. D. Shen,  U. Harms, and T. Lillo, “Soft ferromagnetism in amorphous and nanocrystalline alloys”, Journal of Magnetism and Magnetic Materials, 283 (2004) 223-230.

73*. T. D. Shen and R. B. Schwarz, “Soft magnetism in mechanically alloyed nanostructured materials”, Physical Review B, 72 (2005) 014431-1~8.

74*.  T. D. Shen, R. B. Schwarz, and X. H. Zhang, “Bulk nanostructured alloys prepared by flux-melting”, Applied Physics Letters, 87 (2005) 141906-1~3.

75*. T. D. Shen and R. B. Schwarz, “Lowering critical cooling rate for forming bulk metallic glass”, Applied Physics Letters, 88 (2006) 091903-1-3.

76*. E. Ma, T. D. Shen and X. L. Wu, “Nanostructured metals: less is more”, Nature Materials, 5 (2006) 515-516.

77*. H. Fu, X. T. Zu and T. D. Shen, “Structure and phase transformation of melt-spun Gd5Si2Ge2”, Thermochimica Acta, 445 (2006) 53-56.

78*. Yusheng Zhao, Jianzhong Zhang, Bjorn Clausen, T. D. Shen, George T. Gray III, and Liping Wang, “Thermomechanics of nanocrystalline nickel under high pressure-temperature conditions”, Nano Letters, 7 (2007) 426-432.

79*. T. D. Shen, X. Zhang, K. Han, C. A. Davy, D. Aujla, P. N. Kalu, and R. B. Schwarz, “Structure and properties of bulk nanostructured alloys synthesized by flux-melting”, Journal of Materials Science, 42 (2007) 1638-1648

80*. H. Fu, X.T. Zu, X. He, W.S He, and T. D. Shen, “The effect of low temperature annealing on the structure of Gd5Si2Ge2 Alloy”, Journal of Alloys and Compounds, 431 (2007) 89-92.

81*. Y. Zhao, T. D. Shen, and J. Z. Zhang, “High-P-T nano-mechanics of polycrystalline nickel”, Nanoscale Research Letters, 2 (2007) 476-491.

82*. T. D.  Shen, S. Feng, M. Tang, J.A.Valdez, Y. Wang, and K. E. Sickafus, “Enhanced radiation tolerance in nanocrystalline MgGa2O4”,  Applied Physics Letters, 90 (2007) 263115-1~3.

83*. T.D. Shen, R.B. Schwarz, S. Feng, J.G. Swadener, J.Y. Huang, M. Tang, Jianzhong Zhang, S.C. Vogel, Yusheng Zhao, “Effect of solute segregation on the strength of nanocrystalline alloys: Inverse Hall–Petch relation”, Acta Materialia, 55 (2007) 5007-5013.

84*. T.D. Shen, “Radiation tolerance in a nanostructure: Is smaller better?”, Nuclear Instruments and Methods in Physics Research, Section B: Beam Interactions with Materials and Atoms, 266 (2008) 921-925.

85*. T.D. Shen, “What is the theoretical density of a nanocrystalline material?”, Acta Materialia, 56 (2008) 3663-3671.

86*. Yingguang Liu, Jianqiu Zhou, T.D. Shen, David Hui, “Grain rotation dependent fracture toughness of nanocrystalline materials”, Materials Science and Engineering A 528 (2011) 7684-7687

87*. Yingguang Liu, Jianqiu Zhou, T.D. Shen, David Hui, “Effects of ultrafine nanograins on the fracture toughness of nanocrystalline materials”, Journal of Materials Research. 26 (2011) 1734-1741.

88*. Yingguang Liu, Jianqiu Zhou, T.D. Shen, “A combined dislocation—cohesive zone model for fracture in nanocrystalline materials”, Journal of Materials Research, 27 (2012)694-700.

89* . Yingguang Liu, Jianqiu Zhou, T.D. Shen, “Effect of Nano-Metal Particles on the Fracture Toughness of Metal-Ceramic Composite”, Materials and Design, 45 (2013) 67-71.

90.  焦迎春,沈同德, 梁沁, 章轶, “碳纳米管增强聚甲基丙烯酸甲酯复合材料的研究进展”, 中国塑料,26(10) (2012) 16-23.

91.  焦迎春,沈同德,杨克亚, “聚甲基丙烯酸甲脂/多壁碳纳米管复合材料的制备与电性能”,焦迎春,沈同德,杨克亚, 塑料, 41 (5) (2012) 76-91.

92.  杨克亚,沈同德,“纳米SiO2对PC/ABS/RDP 阻燃体系的协同作用“,塑料, 41(6)(2012)7-10.

93. 冯卫良, 沈同德, “碳纳米管改性磷酸铁锂正极材料的研究进展“, 能源技术,37(11) (2013) 2063-2066.   


 

94*. X. Zhang, O. Alloul, J. Zhu, Q. He, Z.  Luo, H. A. Colorado, N. Haldolaarachchige, D. P. Young, T.D. Shen, S. Wei, and Z. Guo, “A  Iron-core carbon-shell nanoparticles reinforced electrically conductive magnetic epoxy resin nanocomposites with reduced flammability”,  RSC Advances 3 (2013) 9453-9464.


 

95*. Q. He, T. Yuan, X. Yan, D. Ding, Q. Wang, Z. Luo, T. D. Shen, S. Wei,  D. Cao,  Z. Guo, “Flame-retardant polypropylene/ multiwall carbon nanotube nanocomposites: effects of surface functionalization and surfactant molecular weight”,  Macromolecular Chemistry and Physics  215 (2014) 327−340.


 

96. 沈同德, 高欣海, 于开元, “抗辐照纳米材料的研究进展”, 燕山大学学报, 38 (4)(2014)283-298.


 

97*. Q. He, T. Yuan, X. Zhang, X. Yan, J. Guo, D. Ding, M. A. Khan, D. P. Young, A. Khasanov, Z. Luo, J. Liu, T. D. Shen, X. Liu, S. Wei, and Z. Guo, “Electromagnetic field absorbing polypropylene nanocomposites with tuned permittivity and permeability by nanoiron and carbon nanotubes”, The Journal of Physics Chemistry C 118 (42) (2014) 24784−24796.


 

98*. T. D. Shen, S. W. Xin, B. R. Sun, “Influence  of annealing on the mechanical property of iron- and nickel-based nanocrystalline alloys”, Materials Science & Engineering A  627 (2015) 139-144.


 

99*. T. D. Shen, B. R. Sun. S. W. Xin, “Effects of metalloids on the thermal stability and glass forming ability of bulk ferromagnetic metallic glasses”, Journal of Alloys and Compounds  631 (2015) 60-66.


 

100*. T. D. Shen, B. R. Sun. S. W. Xin, “Influence of metalloids and annealing on the fundamental magnetic properties of bulk Fe-(Cr,Mo,Ga)-(P,B,C) metallic glasses”,  Intermetallics  65 (2015) 111-116.


 

101*. Yiran Wang, Qingliang He, Jiang Guo, Huige Wei, Keqiang Ding, Hongfei Lin, Saheel Bhana, Xiaohua Huang, Zhiping Luo, T. D. Shen, Suying Wei, and Zhanhu Guo, “Carboxyl multiwalled carbon-nanotube-stabilized palladium nanocatalysts toward improved methanol oxidation reaction”, ChemElectroChem 2 (2015) 559-570.


 

102*. Yiran Wang, Qingliang He, Keqiang Ding, Huige Wei, Jiang Guo, Qiang Wang, Ryan O’Connor, Xiaohua Huang, Zhiping Luo, T. D. Shen, Suying Wei, and Zhanhu Guoa, “Multiwalled carbon nanotubes composited with palladium nanocatalysts for highly efficient ethanol oxidation”,  Journal of The Electrochemical Society 162 (7) (2015) F755-F763.


 

103*. Jiangnan Huang, Yonghai Cao, Xi Zhang, Yutong Li, Jiang Guo, Suying Wei, Xiangfang Peng, Tong D. Shen, and Zhanhu Guo, “Magnetic epoxy nanocomposites with superparamagnetic MnFe2O4 nanoparticles”, AIP Advances 5 (2015) 097183-1 ~ -15.


 

104*. Zhanhu Guo,   Yiran Wang,   Huige Wei,   Jiurong Liu,  Jinmin Wang,   Jiang Guo,   Xin Zhang,   Brandon Weeks,  T. D. Shen and   Suying Wei , “Electropolymerized polyaniline/manganese iron oxide hybrids with enhanced color switching response and electrochemical energy storage”,  Journal of Materials Chemistry A 3 (2015) 20778-20790.


 

105*. Yiran Wang, Qingliang He, Jiang Guo, Jinmin Wang, Zhiping Luo, Tong D. Shen, Keqiang Ding, Airat Khasanov, Suying Wei, and Zhanhu Guo, “Ultrafine FePd Nanoalloys Decorated Multiwalled Cabon Nanotubes toward Enhanced Ethanol Oxidation Reaction”, ACS Applied Materials & Interfaces 7 (2015) 23920-23931.


 

106*. T.D. Shen, S.W. Xin, B.R. Sun, “Low power loss in Fe65.5Cr4Mo4Ga4P12B5.5C5 bulk metallic glasses”, Journal of Alloys and Compounds 658 (2016) 703-708.


 

107*. Jiang Guo,  Litao Guan,  Huige Wei,  Mojammel A Khan,  Xin Zhang,  Bingbing Li, Qiang Wang,  Brandon L. Weeks,  David P. Young, Tongde Shen,  Suying Wei, and Zhanhu Guo, “Enhanced Negative Magnetoresistance with High Sensitivity of Polyaniline Interfaced with Nanotitania”,Journal of The Electrochemical Society 163 (8) (2016) H664-H671.


 

108*. Hongbo Gu, Jiang Guo, Mojammel Alam Khan, David P. Young, T. D. Shen, Suying Wei and Zhanhu Guo, “Magnetoresistive polyaniline–silicon carbide metacomposites: plasma frequency determination and high magnetic field sensitivity”, Physical Chemistry Chemical Physics 18 (2016) 19536-19543.


 

109*. Yuqing Qiao, Huaping Wang, Xiaoyu Zhang, Peng Jia, Tongde Shen, Xianfeng Hao, Yongfu Tang, Xianhui Wang, Weimin Gao, Lingxue Kong, “Ultrahigh volumetric capacitance biomorphic porous carbon material derived from mold”, Materials Letters 184 (2016) 252-256.


 

110*. Yuqing Qiao, Peng Jia, Xiaoyu Zhang, Ning Cai, Tongde Shen, Xianfeng Hao, Yongfu Tang, Xianhui Wang, Weimin Gao, Lingxue Kong, "One-pot synthesized mesoporous Ni-Co hydroxide for high performance supercapacitors",  Ionics (2016). doi:10.1007/s11581-016-1914-8.


 

111*. J. Y. Cui, K. Y. Li, L. Ren, J. Zhao, T. D. Shen, “Photogenerated Carriers Enhancement in Cu-doped ZnSe/ZnS/L-cys Self-assembled Core-shell Quantum Dots”, Journal of Applied Physics 120 (2016) 184302-1~8.


 

112*. Yu Qing Qiao, Wei Liang Feng, Jing Li, Tong De Shen, “Ultralong cycling stability of carbon-nanotube/LiFePO4 nanocomposites as electrode materials for lithium-ion batteries”, Electrochimica Acta 232C (2017) 323-331.


 

113*. B.R. Sun, S.W. Xin, T.D. Shen, “Low-temperature magnetization and magnetic exchange interactions in Fe40Ni40P14B6 bulk metallic glasses”, Journal of Magnetism and Magnetic Materials 429 (2017) 276-280.


 


 

国际学术会议口头和特邀报告:
  1. “The influence of dislocation structure on formation of nanocrystals by mechanical attrition”, International Symposium on Metastable, Mechanically Alloyed and Nanocrystalline Materials (ISMANAM-94), Grenoble, France, June 27-July 1, 1994.   

2. “Solid solution hardening/softening in nanocrystalline alloys”, Materials Week '95, Cleveland, Ohio, October 29-November 2, 1995.

3. "V/MgAl2O4 composites for hostile environment applications-Part I: processing", 22nd Annual Conference on Composites, Advanced Ceramics, Materials, and Structures: A, Cocoa Beach, Florida, U. S. A., January 20-24, 1998.

4. "V/MgAl2O4 composites for hostile environment applications-Part II: properties", 22nd Annual Conference on Composites, Advanced Ceramics, Materials, and Structures: A, Cocoa Beach, Florida, U. S. A., January 20-24, 1998.

5. “Synthesis and properties of Pd-containing bulk glassy alloys”, 1998 MRS Fall Meeting  (Symposium MM: Bulk Metallic Glasses), Boston, Massachusetts, U. S. A., November 30 - December 4, 1998.

6. “Bulk amorphous Fe-based alloys with soft magnetic properties”, 1999 MRS Spring Meeting (Symposium I: Amorphous and Nanocrystalline Materials for Hard and Soft Magnetic Applications), San Francisco, California, U. S. A., April 5-9, 1999.

7. “Thermal, transport and magnetic properties of bulk Pd-Ni-Fe-P metallic mlasses”, the 2000 TMS Fall Meeting, St. Louis, Missouri, U. S. A., October 8–12.

8. “Bulk Fe-based metallic glasses with extremely soft ferromagnetic properties”, the 2001 International Symposium on Metastable, Mechanically Alloyed and Nanocrystalline Materials (ISMANAM 2001), Ann Arbor, Michigan, U. S. A., June 24-29, 2001.

9. “Recent advances in bulk metallic glass”, the 2001 International Symposium on Metastable, Mechanically Alloyed and Nanocrystalline Materials (ISMANAM 2001), Ann Arbor, Michigan, U. S. A., June 24-29, 2001.

10. “Stability of supercooled Pd40Ni40-xCuxP20 liquids”, 2002 TMS Annual Meeting & Exhibition, Seattle, Washington, U. S. A., February 17–21, 2002.

11.  “Glass formability and stability in Pd-Ni-Cu-P alloys”, 2002 MRS Fall Meeting (Symposium CC: Supercooled Liquids, Glass Transition, and Bulk Metallic Glasses), Boston, Massachusetts, U. S. A., December 2-6, 2002.

12. “Low-temperature magnetization and spin-wave excitation in bulk Fe-based amorphous glasses”, 2003 TMS Annual Meeting & Exhibition, San Diego, California, U. S. A.,  March 2–6, 2003.

13. “What is the lowest achievable critical cooling rate in Pd-based glasses”, 2003 TMS Annual Meeting & Exhibition, San Diego, California, U. S. A., March 2–6,  2003.

14. "Bulk metallic glass gasket for high pressure: in situx-ray diffraction", the SMEC (Study of matter at extreme conditions) Conference (Symposium 14:High-pressure structural study of metals.), Miami, Florida, U. S. A., March 24-27, 2003.

15. “Soft ferromagnetism in nanocrystalline alloys”, 10th International Symposium on Metastable, Mechanically Alloyed and Nanocrystalline Materials (ISMANAM 2003), Foz do Iguaçu, Brazil, August 24 - 28, 2003.

16. “How far are we from achieving homogeneous nucleation in a bulk metallic glass?”, the 3rd International Conference on Bulk Metallic Glasses, Beijing, China, October 12-16, 2003.

17. “High-strength, high conductivity bulk nanostructured Ag-Cu alloys”, Materials Science & Technology 2003, Chicago, Illinois, November 9-12, 2003.

18. “Mechanical and physical properties of bulk Ag-Cu nanostructured alloys prepared by slow melt quenching”, 2003 MRS Fall Meeting (Symposium Q: Mechanical Properties of Nanostructured Materials and Nanocomposites), Boston, Massachusetts, U. S. A., December 1-5, 2003.

19. “The decomposition of Pd40Ni40P20 bulk metallic glass”, International Field Emission Symposium (IFES 04), Seggau Castle by Graz, Austria, July 12 - 16, 2004.

20. “Magnetic microstructure of bulk metallic glasses”, the Fourth International Bulk Metallic Glasses Conference, Gatlinburg, Tennessee, U. S. A., May 1-5, 2005.

21. “Fabrication and characterization of nanostructured CuAg (Ag-40at%Cu)”, IMS 2005, Honolulu, Hawaii, U. S. A., July 31 – August 4, 2005.

22. “Structure and properties of bulk nanostructured materials prepared by flux-melting”, the 6th International Workshop on Advanced Intermetallics and Metallic Materials, Yangzhou, Jiangsu, China, October 9-15, 2005.

23. “Nanocrystalline Fe(Al,Si) alloys: hardening by annealing”, 2006 TMS Annual Meeting & Exhibition, San Antonio, Texas, U. S. A., March 12-16, 2006.

24. “Influence of dislocation configuration on the mechanical behavior of nanocrystalline materials”, 2006 MRS Spring Meeting, San Francisco, California, U. S. A., April 17-21, 2006.

25. “Radiation tolerance in nanocrystalline materials: thermodynamics, kinetics, and microstructural evolution”, CAARI 2006: 19th International Conference on the Application of Accelerators in Research and Industry, Fort Worth, Texas,  USA, August 20 - 25, 2006.

26. “Strength of nanocrystalline metals: influence of recovery and recrystallization”, 2007 TMS Annual Meeting & Exhibition, Orlando, Florida, U. S. A., February 25-March 1, 2007.

27. “Effect of solute segregation on the hardness of nanocrystalline alloys”, 2007 TMS Annual Meeting & Exhibition, Orlando, Florida, U. S. A., February 25-March 1, 2007.

28. “Nanostructure under irradiation: is smaller better?”, 2008 TMS Annual Meeting & Exhibition, New Orleans, Louisiana, U. S. A., March 9-13, 2008.

29. “Multiple deformation in bulk nanocrystalline silver”, 2008 TMS Annual Meeting & Exhibition, New Orleans, Louisiana, U. S. A., March 9-13, 2008.

30. “Magnetic structure and property of bulk ferromagnetic metallic glasses”, International Symposium of Amorphous Alloys, Hangzhou, China, November 19-22, 2008.

31. “Tensile deformation of bulk nanocrystalline silver studied by in situ synchrotron x-ray diffraction”,  International Conference on Mechanical Properties of Materials,Hangzhou, China, May 24-28, 2010.

32. “Soft Magnetism in Stressed Iron-based Nanocrystalline Alloys”, IUMRS-ICAM2013 International Conference on Advanced Materials, Qingdao, China, September 22-28, 2013.

33.“Magnetic Microstructure-Property Relations in Iron-based Bulk Metallic Glasses”, IUMRS-ICAM2013 International Conference on Advanced Materials, Qingdao, China, September 22-28, 2013.
 34. “Hardening by annealing and abnormal Hall-Petch relationship in nanocrystalline elements and alloys”, 2nd International symposium on Metastable Materials Science & Technology, Qinhuangdao, China, 2015.10.12-10.16.   

35. “Low power loss in Fe65.5Cr4Mo4Ga4P12B5.5C5 bulk metallic glasses“, 23rd  International Symposium on Metastable, Amorphous and Nanostructured Materials, Kasugano International Forum, Nara, Japan, July 3-8, 2016.

36. “Improving the thermal stability, glass forming ability and ferromagnetism of bulk ferromagnetic metallic glasses by metalloids”, IUMRS-ICA 2016 Symposium G: Amorphous and High-entropy Alloys, Qingdao, China, Oct. 20-24, 2016.
 37. “Hardening by annealing and abnormal Hall-Petch relationship in nanocrystalline elements and alloys”,  2017 TMS Annual Meeting & Exhibition,San Diego, California, USA, Feb. 26 – March 2, 2017.
 38. “The origins of excellent soft magnetism in Fe65.5Cr4Mo4Ga4P12B5.5C5 bulk metallic glasses ”,  2017 TMS Annual Meeting & Exhibition,  San Diego, California, USA, Feb. 26 – March 2, 2017.   


 


专利:   

   沈同德, 李静,“两性碳纳米管分散粉末的制备”,专利号: CN102275899A。
    (美国专利)T.D. Shen and J. Li,Dispersible carbon nanotubes and method for preparing same, 12/792428。
     沈同德,冯卫良, 李静,“含有三维空间导电网络的锂离子电池纳米复合正、负极材料及制备方法”,专利申请号: 201210248503.1。
     沈同德, “一种制备块体非晶的熔剂覆盖及真空纯化方法”,专利申请号: 201310202147.4。
     沈同德, “一种提高合金非晶形成能力的反复熔化-凝固处理方法”,专利申请号: 201310202112.0。
     沈同德, “一种制备具有超软铁磁性能的铁基非晶合金的方法”,专利申请号: 201310202160.X。   

科研成果及奖励

 

科研成果:

       在Nature Materials、 Nano Letters、 PNAS、 Acta Materialia、Physical Review B、 Applied Physics  Letters等国际著名学术刊物发表SCI 收录论文100余篇, SCI引用3700余次,  H因子31(Google Scholar)。

        主要创新性成果: 提出纯元素通过压力及晶粒尺寸细化两种方式进行非晶转变的机制; 晶粒尺寸对纳米晶材料弹性性能的定量影响;  融渣融化法制备具有高玻璃形成能力和优异软磁性能的块体非晶材料; 提出描述纳米材料软磁磁性的普适理论模型;  融渣融化法制备具有优异力学特性的块体纳米晶材料; 利用循环熔化/凝固法大幅度提高块体非晶合金的玻璃形成能力;  发现和解释纳米材料的超强抗辐射特性; 对纳米材料中反常的Hall-Petch关系提出溶质晶偏聚的新解释;高性能锂离子电池纳米复合电极材料。

 

主要奖励:

2007年,美国洛斯阿拉莫斯国家实验室,杰出表现奖    
2008年,“南京工业大学--南京高新技术产业开发区”三创载体领军人才    
2009年,“江苏省高层次创新创业人才引进计划”(创新类别)    
2011年,微纳米材料制备、力学性能及工业应用获江苏省科学技术三等奖    
2016年,新型亚稳材料的制备、性能及应用获第六届中国侨界(创新成果)贡献奖          

  

 

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