欢迎登录材料期刊网

材料期刊网

高级检索

综述了组合材料芯片技术在钛合金研究中应用的新进展.利用组合材料芯片技术在短周期内制备出合金元素梯度变化的多元钛合金样品,由于样品的加工状态和热处理条件相同,可以确定某种合金元素含量与整个钛合金体系组织和力学性能的定量关系.利用多种表征手段,从样品库中系统地分析组织和力学性能的变化规律并筛选出目标成分,显示出组合材料芯片技术在钛合金相变研究和合金设计中的优势.

The progress of COMBI which is widely used in the titanium alloys research is summarized. The COMBI technique has already demonstrated its advantages and potentials in the study of materials transformation and also in the design of alloys with the help of preparation of compositionally graded titanium alloys that are under the same condition in order to explore the relationship between alloying element contents and microstructure/properties to find target compositions for multi-element titanium alloy systems by various methods of characterization.

参考文献

[1] Xiang XD;Sun XD;Briceno G;Lou YL;Wang KA;Chang HY .A COMBINATORIAL APPROACH TO MATERIALS DISCOVERY[J].Science,1995(5218):1738-1740.
[2] 刘茜,陈伟,刘庆峰,归林华,朱丽慧,王利.组合材料芯片技术应用最新进展--新型合金材料的快速发现和优选[J].科技导报,2007(23):64-68.
[3] Van Dover R B;Schneemeyer L F .Fleming R M Discovery of a useful thin-film dielectric using a composition-spread approach[J].Nature,1998,392:162.
[4] Chang H;Tacheuchi I;Xiang X D .A low-loss composition region identified from a thin-film composition spread of (Ba_(1-x-y) Sr_xCa_y)TiO_3[J].Applied Physics Letters,1999,74:1165.
[5] Danielson E;Golden J H;Mcfarland E W .A combinatorial approach to the discovery and optimization of luminescent materials[J].Nature,1997,389:944.
[6] Wang J;Yoo Y K;Gao C .A blue photo luminescent composite material from a combinatorial library[J].Science,1998,279:1712.
[7] Lou Lan;Liu Qiangfeng;Liu Qian .Luminescence properties and mechanism of Gd_(1-x-y),AlO_3:Eu_x,RE_y[J].Chinese Physics Letters,2005,22:132.
[8] Liu Qingfeng;Liu Qian;Luo Lan .Preparation and luminescent properties of Eu-doped Ln_2O_3 (Ln=Gd,Lu) thin film by citrate sol-gel process[J].Ceramics International,2004,30:1703.
[9] Shen Cai;Liu Qian;Liu Qingfeng .Photoluminescence properties of Er~(3+)-doped Ba_(0.5) Sr_(0.5) TiO_3 prepared by sol-gel synthesis[J].Materials Science and Engineering B,2004,111:31.
[10] G Briceno;Chang H;Sun X D .A class of cobalt oxide magnetoresistance materials discovered with combinatorial synthesis science[J].Science,1995,270:273.
[11] Yoo Y K;Duewer F;Yang H .Room-temperature electronic phase transitions in the continuous phase diagrams of pe-rovskite manganites[J].Nature,2000,406:704.
[12] Gao C;Duewer F;Xiang Xiaodong .Quantitative microwave evanescent microscopy[J].Applied Physics Letters,1999,75:3005.
[13] Seung Min Han;R. Shah;R. Banerjee .Combinatorial studies of mechanical properties of Ti-Al thin films using nanoindentation[J].Acta materialia,2005(7):2059-2067.
[14] Takeda T;Steen W M;West D R F .User cladding with mixed powder feed[J].Proceedings of ICALEO'84,1984,44:151.
[15] Steen W M;Vilar R M et al.Alloy system analysis by laser cladding[J].Proceedings of ICALEO'92,1992,52:278.
[16] 朱丽慧,朱烁金,刘茜,刘庆峰,王利.组合材料芯片技术在Zn-Al合金镀层组分优选中的应用[J].上海大学学报(自然科学版),2008(05):492-497.
[17] Nag S .ω-Assisted nucleation and growth of a precipitates in the Ti-5Al-5Mo-5V-3Cr-0 5Fe β titanium alloy[J].ACTA MATERIALIA,2009,57:2136.
[18] Keicher D M;Miller W D .LENS~(TM) moves beyond RP to direct fabrication[J].Metal Powder Report,1998,53:26.
[19] 郑伟涛.薄膜材料与薄膜技术[M].北京:化学工业出版社,2003
[20] Banerjee R .Microstructural evolution in laser deposited compositionally graded α/β titanium-vanadium alloys[J].Acta Materialia,2003,51:3277.
[21] Collins PC.;Banerjee R.;Banerjee S.;Fraser HL. .Laser deposition of compositionally graded titanium-vanadium and titanium-molybdenum alloys[J].Materials Science & Engineering, A. Structural Materials: Properties, Misrostructure and Processing,2003(1/2):118-128.
[22] Banerjee R .Precipitation of grain boundary a in a laser deposited compositionally graded Ti-8Al-xV alloy-an orientation microscopy study[J].Acta Materialia,2004,52:377.
[23] Wang K .The use of titanium for medical applications in the USA[J].Materials Science and Engineering,1996,213:134.
[24] Long M;Rack HJ .Titanium alloys in total joint replacement--a materials science perspective.[J].Biomaterials,1998(18):1621-1639.
[25] Lowman E W .Osteoarthiritis[J].Journal of Americal Med Acad,1955,157:487.
[26] Rodolfo Villa;Celina R. Ortiz;Stephanie Tapia .In Vitro Biocompatibility Studies of Fibroblast Cells on Ti-Ta Alloys[J].Materials transactions,2002(12):2991-2994.
[27] Zhou Y L et al.Effects of Ta content on Young's modulus and tensile properties of binary Ti-Ta alloys for biomedical applications[J].Materials Science and Engineering A:Structural Materials Properties Microstructure and Processing,2004,371:283.
[28] Ahmed T A;Long M;Silverstri J.A new low modulus biocompatible titanium alloy[A].Science Technology,1996:1760.
[29] Wang K.The characterization of Ti-12Mo-6Zr-2Fe,A new biocompatible titanium alloy developed for surgical implants[A].Warrendale,PA:Mineral,metals and materials society,1993:2697.
[30] Nag S;Banerjee R;Fraser HL .A novel combinatorial approach for understanding microstructural evolution and its relationship to mechanical properties in metallic biomaterials.[J].Acta biomaterialia,2007(3):369-376.
[31] Banerjee R et al.A novel combinatorial approach to the development of beta titanium alloys for orthopaedic implants[J].Materials Science and Engineering C:Biomimetic and Supramolecular Systems,2005,25:282.
上一张 下一张
上一张 下一张
计量
  • 下载量()
  • 访问量()
文章评分
  • 您的评分:
  • 1
    0%
  • 2
    0%
  • 3
    0%
  • 4
    0%
  • 5
    0%