V含量对TaVN复合膜微结构、力学性能和摩擦性能的影响

无机材料学报, 2013, 28(7): 769-774. doi: 10.3724/SP.J.1077.2013.12498

V含量对TaVN复合膜微结构、力学性能和摩擦性能的影响

1.江苏科技大学江苏省先进焊接技术重点实验室,镇江,212003

2.江苏科技大学江苏省先进焊接技术重点实验室,镇江,212003

3.江苏科技大学江苏省先进焊接技术重点实验室,镇江,212003

4.江苏科技大学江苏省先进焊接技术重点实验室,镇江,212003

基金项目: Natural Science Foundation of Jiangsu Province(BK2008240) 国家自然科学基金(51074080) 江苏省自然科学基金(BK2008240).National Natural Science Foundation of China(51074080)

关键词： TaVN复合膜 , 磁控溅射 , 力学性能 , 摩擦性能

Influence of V Content on Microstructure, Mechanical and Friction Properties of TaVN Composite Films

Keywords： TaVN composited films , magnetron sputtering technique , mechanical properties , friction properties

采用磁控溅射仪制备了一系列不同V含量的TaVN复合膜,利用X射线衍射仪研究复合膜以及磨痕的相组成,利用纳米压痕仪表征复合膜的硬度,采用高温摩擦磨损实验机研究了复合膜的室温和高温摩擦性能.结果表明:TaVN复合膜的微结构为面心立方结构,随着V含量的增加,衍射峰择优取向由(200)转变为(111);TaVN薄膜的显微硬度随着V含量增加,先增加后降低,在V含量为18.25 at％时,显微硬度达到最大值,为32.3 GPa;在常温下,TaVN复合膜的摩擦系数随着V含量的增加而降低；当温度从室温升高到800℃,薄膜的摩擦系数先升高后降低.采用晶体化学理论讨论了TaVN复合膜和TaN单层膜在高温下的摩擦机理.

参考文献

[1]	Na S M,Park I S,Park S Y.Electrical and structural properties of Ta-N thin film and Ta/Ta-N multilayer for embedded resistor.Thin Solid Film,2008,516(16):5465-5469.
[2]	Kang S M,Yoon S G.Control of electrical resistivity of TaN thin films by reactive sputtering for embedded passive resistors.Thin Solid Films,2008,516(11):3568-3571.
[3]	Riekkinena T,Molariusa J,Laurilab T.Reactive sputter deposition and properties of TaN thin films.Microelectronic Engineering,2002,64(1-4):289-297.
[4]	田民波.薄膜技术与薄膜材料.北京:清华大学出版社,2006:774-820.
[5]	Cuong N D,Kim D J,Kang B D.Structural and electrical characterization of tantalum nitride thin film resistors deposited on AIN substrates for(Π)-type atteruator applications.Materials Science and Engineering B,2006,135(2):162-165.
[6]	Leng Y X,Sun H,Yang P,et al.Biomedical properties of tantalum nitride films synthesized by reactive magnetron sputtering.Thin Solid Films,2001,398-399:471-475.
[7]	Hubner R,Hecker M,Matter N,et al.Structure and thermal stability og graded Ta-TaN diffusion barriers between Cu and SiO2.Thin Solid Films,2003,437(1/2):248-256.
[8]	Chatterjee S,Kuo Y,Lu J.Electrical reliability aspects of HfO2 high-kgate dielectrics with TaN metal gate electrodes under constant voltage stress.Microelectronics Reliability,2006,46(1):69-76.
[9]	Hasegawa H,Kimura A,Suzuki T.Microhardness and structure analysis of(Ti,A1)N,(Ti,Cr)N,(Ti,Zr)N,(Ti,V)N films.J.Vac.Sci.Technol.A,2000,18(3):1038-1040.
[10]	Hsieh J H,Li C,Wang C M,et al.Boundary-free multi-element barrier films by reactive co-sputtering.Surf.Coat.Technol.,2005,198(1/2/3):335-339.
[11]	Liu D,Zhou B,Yoon S H,et al.Effects of the structural layer in MEMS substrates on mechanical and electrical properties of Pb(Zr0.52Ti0.48)O3films.Ceram.Int.,2011,37(7):2821-2828.
[12]	Nicolet M A.Ternary amorphous metallic thin films as diffusion barriers for Cu metallization.Appl.Surf.Sci.,1995,91(1-4):269-276.
[13]	Levi G,Kaplan W D,Bamberger M.Structure refinement of titanium carbonittide(TiCN).Mater.Lett.,1998,35(5/6):344-350.
[14]	Knotek O,Loffler F,Kramer G.Arc-deposited Ti-Zr-N coatings on cemented carbides for use in interrupted cutting,Surf.Coat.Technol.,1991,49(1/2/3):325-329.
[15]	Mayrhofer P H,Hovsepian P Eh,Mitterer C,et al.Calorimetric evidence for frictional self-adaptation of TiAlN/VN superlattice coatings.Surf.Coat.Technol.,2004,177-178:341-347.
[16]	Kutschej K,Mayrhofer PH,Kathrein M,et al.Influence of oxide phase formation on the tribological behavior of Ti-Al-V-N coatings.Surf.Coat.Technol.,2005,200(5/6):1731-1737.
[17]	Gassner G,Mayrhofer P H,Kutschej K,et al.A new low friction concept for high temperatures:lubricious oxide formation on sputtered VN coatings.Tribology Letters,2004,17(4):751-756.
[18]	Ertürk E,Knotek O,Burgmer W,et al.Ti(C,N)coatings using the arc process.Surf.Coat.Technol.,1991,46(1):39-46.
[19]	Hovsepian P Eh,Munz W D.Recent progress in large-scale production of nanoscale multilayer/superlattice and coatings.Vacuum,2002,69(1/2/3):27-36.
[20]	Zhou Z,Rainforth W M,Luo Q,et al.Wear and friction of TiAlN/VN coatings against Al2O3 in air at room and elevated temperatures.Acta Materialia,2010,58(8):2912-2925.
[21]	Munz W D,Lewis D A,Hovsepian P Eh.Properties of various large-scale fabricated TiAlN-and CrN-based superlattice coatings grown by combined cathodic arc-unbalanced magnetron sputter deposition.Surface and Coating Technology,2000,125(1/2/3):269-277.
[22]	Fateh N,Fontalvo G A,Gassner G,et al.Influence of high-temperature oxide formation on the tribological behavior of TiN and VN coatings.Wear,2007,262(9/10):1152-1158.
[23]	Luo Q.Temperature dependent friction and wear of magnetron sputtered coating TiA1N/VN.Wear,2011,271(9/10):2058-2066.
[24]	Ali E.A Crystal chemical approach to formulation of self-lubrication nanocomposite coatings.Surf.Coat.Technol.,2005,200(5/6):1792-1796.
[25]	Erdemir A.Acrystal-chemical approach to lubrication by solid oxides.Tribology Letters,2000,8(2):97-102.

上一张下一张

计量

下载量()
访问量()

作者相关

文章评分

您的评分：
1

0%
2

0%
3

0%
4

0%
5

0%

材料期刊网