物理学报
物理學報
물이학보
2013年
3期
277-282
,共6页
杨铎%钟宁%尚海龙%孙士阳%李戈扬
楊鐸%鐘寧%尚海龍%孫士暘%李戈颺
양탁%종저%상해룡%손사양%리과양
磁控溅射%铝基纳米复合薄膜%微结构%力学性能
磁控濺射%鋁基納米複閤薄膜%微結構%力學性能
자공천사%려기납미복합박막%미결구%역학성능
magnetron sputtering%aluminum matrix nanocomposite film%microstructure%mechanical property
采用Al和TiN靶通过磁控共溅射方法,制备了一系列Ti:N≈1的不同(Ti, N)含量的铝基纳米复合薄膜,利用X射线能量分散谱仪、X射线衍射仪、透射电子显微镜和纳米力学探针表征了薄膜的成分、微结构和力学性能,研究了(Ti, N)含量对复合薄膜微结构和力学性能的影响.结果表明:Ti, N原子的共同加入使复合薄膜形成了同时具有置换固溶和间隙固溶特征的“双超过饱和固溶体”,薄膜的晶粒随着溶质含量的增加逐步纳米化,并进一步形成非晶结构,晶界区域形成溶质原子的富集区.相应地,复合薄膜的硬度在含1.8 at.%(Ti, N)时就可迅速提高到3.9 GPa;随着TiN含量的增加,薄膜的硬度进一步提高到含17.1 at.%(Ti, N)时的8.8 GPa.以上结果显示出Ti和N“双超过饱和固溶”对Al薄膜极其显著的强化效果.
採用Al和TiN靶通過磁控共濺射方法,製備瞭一繫列Ti:N≈1的不同(Ti, N)含量的鋁基納米複閤薄膜,利用X射線能量分散譜儀、X射線衍射儀、透射電子顯微鏡和納米力學探針錶徵瞭薄膜的成分、微結構和力學性能,研究瞭(Ti, N)含量對複閤薄膜微結構和力學性能的影響.結果錶明:Ti, N原子的共同加入使複閤薄膜形成瞭同時具有置換固溶和間隙固溶特徵的“雙超過飽和固溶體”,薄膜的晶粒隨著溶質含量的增加逐步納米化,併進一步形成非晶結構,晶界區域形成溶質原子的富集區.相應地,複閤薄膜的硬度在含1.8 at.%(Ti, N)時就可迅速提高到3.9 GPa;隨著TiN含量的增加,薄膜的硬度進一步提高到含17.1 at.%(Ti, N)時的8.8 GPa.以上結果顯示齣Ti和N“雙超過飽和固溶”對Al薄膜極其顯著的彊化效果.
채용Al화TiN파통과자공공천사방법,제비료일계렬Ti:N≈1적불동(Ti, N)함량적려기납미복합박막,이용X사선능량분산보의、X사선연사의、투사전자현미경화납미역학탐침표정료박막적성분、미결구화역학성능,연구료(Ti, N)함량대복합박막미결구화역학성능적영향.결과표명:Ti, N원자적공동가입사복합박막형성료동시구유치환고용화간극고용특정적“쌍초과포화고용체”,박막적정립수착용질함량적증가축보납미화,병진일보형성비정결구,정계구역형성용질원자적부집구.상응지,복합박막적경도재함1.8 at.%(Ti, N)시취가신속제고도3.9 GPa;수착TiN함량적증가,박막적경도진일보제고도함17.1 at.%(Ti, N)시적8.8 GPa.이상결과현시출Ti화N“쌍초과포화고용”대Al박막겁기현저적강화효과.
A series of aluminum matrix nanocomposite films are synthesized by magnetron sputtering of Al and TiN targets. The com-position, microstructure and mechanical property of the composite film are characterized by energy dispersive spectroscopic, X-ray diffraction, transmission electron microscope and nanoindenter. The influences of (Ti, N) content of supersaturated solute Ti,N atoms on the microstructure and mechanical property of the composite films are investigated. The results reveal that the composite film with adding Ti,N atoms together forms a dual-supersaturated solid solution exhibiting both features of substitutional and interstitial solid solution. Higher solute content induced gradual evolutions of nanocrystallization and amorphization of grains in film and solute en-richment occured at the grain boundaries. Correspondingly, the composite film containing 1.8 at.%(Ti, N) can rapidly reach a hardness of 3.9 GPa, and further increasing TiN content to 17.1 at%(Ti, N) the film hardness achieves 8.8 GPa demonstrating the significant strengthening effect of dual-supersaturation of Ti and N on aluminum film.
