Acta Metall Sin  1994, Vol. 30 Issue (13): 1-21    DOI:

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PHASE TRANSFORMATION FROM AN AMORPHOUS ALLOY INTO NANOCRYSTALLINE MATERIALS

LU Ke (National Key Laboratory for RSA; Institurte of Metal Research;Chinese Academy of Sciences;Shenyang)

LU Ke (National Key Laboratory for RSA; Institurte of Metal Research;Chinese Academy of Sciences;Shenyang). PHASE TRANSFORMATION FROM AN AMORPHOUS ALLOY INTO NANOCRYSTALLINE MATERIALS. Acta Metall Sin, 1994, 30(13): 1-21.

Abstract References Related Articles Recommended Metrics Download:  PDF(1576KB)  Export:  BibTeX | EndNote (RIS)       Abstract  Polycrystalline materials with nanometer-sized grains,or called nanocrystalline materials, can be synthesized by crystallization of amorphous alloys. This new method for preparation of nanocrystalline materials has drawn much intensive investigations in recent years. A review is made of the synthesis method and the transformation process from the amorphous to the nanocrystalline phases, including the transformation kinetics,thermodynamics, and the transformation micromechanism. Key words:  amorphous alloy      nanocrystalline material      phase transformation      kinetics      thermodynamics      crystallization method      Service E-mail this article Add to citation manager E-mail Alert RSS （） Articles by authors URL:  https://www.ams.org.cn/EN/     OR     https://www.ams.org.cn/EN/Y1994/V30/I13/1 1BirringerR,HerrU,GleiterH．TransJpnInstMetSuppl,1986:27:432GleiterH,ProgMaterSci,1989;33:2233SiegelRW,In:Fujita,FEed．,PhysicsofNewMaterials,Springer-Verlag,Heidelberg,19924ChokshiAH,RosenA,KarehJ,GleiterH．ScriptaMetali,1989;23:16795LuK,WeiWD,WangJT．ScriptaMetallMater,1990:24:23196LuK,SuiML．ScriptaMetallMater,1993;28:14657KarehJ,BirringerR,GleiterH．Nature,1987;330:5568SiegelRW．In:NastasiMAetaleds．MechanicalPropertiesandDeformationBehavtorofMaterialshavingUltrafineMicrostructures,Kluwer,Dordrecht,1993:inprint9In:KearBH,SiegelRW,TsakalakosTeds．NanostructuredMaterials,PergamonPress,NewYork,199210FechtHJ,HellsteinE,FuZ,JohnsonWL．MetallTransA,1990:Z1A:233311LuK,WangJT．JCrystalGrowth,1989;94:44912LuK,WangJT,JCrystalGrowth,1991;112:525;ibid,1991;113:24213LuK,WangJT．ActaMetallSinica,1991:27:B3814LuK,WangJT,WeiWD．JApplPhys,199l;69:52215TongHY,WangJT,DingBZ,JiangHG,LuK．JNon-crystSol,1992;150:44416LiuXD,WangJT,DingBZ．ScriptaMetallMater,1993;28:5917DongZF,LuK,WeiWD．ActaMetallSinica,1993;accepted18NicolausMM,SinningH-R,HaessnerF．MaterSciEng,1992;A150:10119GuoHQ,ReiningerT,KronmullerH,RappM,SkumrevVKh．PhysStatSol,1991;A127:51920SuiML,XiongLY,DengW,LuK,PatuS,HeYZ．JApplPhys,1991:69:445121SuiML,LuK,HeYZ,PhiloMagB,1991:63:99322SuiML,LuK,DengW,XiongLY,PatuS,HeYZ．PhysReyB,1991;B44:646623LuK,WeiWD,WangJT．JApplPhys,1991;69:734524LuK．ScriptaMetallMater,1991;25:204725LuK．NanostructuredMater,1993;2:inprint26LiuXD,ZhuJ,WangJT．ChinesePhysLett,1993;10:23827LiuXD,WangJT,DingBZ．JMaterSciTech,1993:9:10428DingBZ,TongHY,WangJT．ScriptaMetallMater,1993;28:110729LuK,WangYZ,WeiWD,LiYY．AdvCryoMater,1991:38:28530LiuXD,etal,tobepublished31LuK,WangJT,WeiWD．ScriptaMetallMater,1991;25:61932LuK,WangJT,WeiWD．JPhysD:ApplPhys,1992;25:80833LuK,LuckR,PredelB．ZMetallkd,1993;48(11)34TongHY,privateCommunication35DaviesHA,In:LuborskyFE．ed．,AmorphousMetallicAlloys,London,Butterworth,198336HeroldU,KosterU．In:GuntherodtHJ,BeckHeds．,GlassyMetalsI,Springer,NewYork,1981;22537LiuXD,etal,NanostruMater,1993;2:6338SchaeferHE,WurschumR,BirringerR,GleiterH．PhysRevB,1988:B38:954539SkandanG,HahnH,ParkerJC．ScroptaMetallMater,1991;25:238940SuiML,XiongLY,DengW,LuK,PatuS,HeYZ．MalerForum,1992;105-110:124941TongHY,DingBZ,WangJT,LuK,JiangJ,ZhuJ．JApplPhys,1992;72:512442LiuXD,etal,tobepublishedinJApplPhys,199343SuiML,PatuS,HeYZ．ScriptaMetallMater,1991;25:153744LuK,LuckR,PredelB．ActaMetallMater,1993:submitted45AvramiM．JChemPhys,1939;7:1103;ibid,1940;8:212;ibid,1941:9:17746LuckR,LuK,FrantzW．ScriptaMetallMaler,1993:28:107147LuK,WangJT,JNon-crystSol,1990:117//118:71648ChristianJW,ThetheoryofTransformationinMetalsandAlloys,2ndEd．PergamonPress,Oxford,197549KissingerHE．AnalChem,1957:29:170250LuK,LuckR,PredelB．JNon-crystSol,1993:156-158:58951RuppJ,BirringerR．PhysRevB,1987;B36:788852SuiML,LuK．ActaMetallSinica,1993:accepted53FechtHJ．ActaMetallMater,1990;38:192754WagnerM,PhysRevB,1992;45:63555LuK,ScienceinChina．1993,Submitted56TongHY,DingBZ,JiangHG,LuK,WangJT,HuZQ．JApplPhys,1993;inprint57ThompsonCV,GreerAL,DrehmanAJ．In:MasumotoT,SuzukiKeds．,Proc4thIntConfRapidlyQuenchedMetals,JpnInstMetals,Sendai,1982．58LuK,PhDThesis,InstMetalResAcademiaSinica,1989．59LuK,WangJT,DongL．ActaMetallSinica,1991;27:B3160LuK,WangJT．ScienceinChina,1992;35:1267;ibid,1992;35:127361LuK,LuckR,PredelB,ScriptaMetallMater,1993;28:1387 [1] BAI Jiaming, LIU Jiantao, JIA Jian, ZHANG Yiwen. 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