引文
[1]艾兴.高速切削加工技术[M].北京:国防工业出版社,2004.
[2]Klocke F, Krieg T. Coated tools for metal cutting-features and applications [J]. Annals of the CIRP,1999,48(2):515-525.
[3]王西彬,解丽静.超高速切削技术及其新进展[J].中国机械工程,2000,11(1):190-194.
[4]艾兴,刘战强,赵军,等.高速切削刀具材料的进展和未来[J].制造技术与机床,2001,8:21-25.
[5]Liu Z Q, Wan Y, Ai X. Recent developments in tool materials for high speed machining [J]. Materials Science Forum,2004,471-472:438-442.
[6]刘战强,万熠,周军.高速切削刀具材料及其应用[J].机械工程材料,2006,30(5):1-4.
[7]姚福新,李长河.高速切削加工刀具材料[J].精密制造与自动化.2010,1:5-8.
[8]王宝友,崔丽华.涂层刀具的涂层材料、涂层方法及发展方向[J].机械,2002,29(4):63-65.
[9]Kalss W, Reiter A, Derflinger V, et al. Modern coatings in high performance cutting applications [J]. International Journal of Refractory Metals and Hard Materials,2006,24(5): 399-404.
[10]Klocke F, Krieg T, Gerschwiler K, et al. Improved cutting processes with adapted coating systems [J]. Annals of the CIRP,1998,47(1):65-68.
[11]Hedenqvist P, Olsson M, Wallen P, et al. How TiN coatings improve the performance of high speed steel cutting tools [J]. Surface and Coatings Technology,1990,41(2):243-256.
[12]Chen L, Du Y, Xiong X, et al. Improved properties of Ti-Al-N coating by multilayer structure [J]. International Journal of Refractory Metals and Hard Materials,2011,29(6):681-685.
[13]Antunes R A, Rodas A C D, Lima N B, et al. Study of the corrosion resistance and in vitro biocompatibility of PVD TiCN-coated AISI 316L austenitic stainless steel for orthopedic applications [J]. Surface and Coatings Technology,2010,205(7):2074-2081.
[14]Lee J K, Yang G S. Preparation of TiAlN/ZrN and TiCrN/ZrN multilayers by RF magnetron sputtering [J]. Transactions of Nonferrous Metals Society of China,2009,19(4):795-799.
[15]Chen L, Du Y, Yin F, et al. Mechanical properties of (Ti,Al)N monolayer and TiN/(Ti,Al)N multilayer coatings [J]. International Journal of Refractory Metals and Hard Materials,2007, 25(1):72-76.
[16]方斌,黄传真,许崇海,等.涂层刀具的研究现状[J].机械工程师,2005,(10):21-24.
[17]赵海波,周彤,梁红樱,等.刀具涂层的分类与应用[J].工具技术,2005,39(12):14-17.
[18]刘毅,董英武.涂层刀具的分类及特点[J].机械工程师,2007,(6):142.
[19]余东海,王成勇,张凤林.刀具涂层材料研究进展[J].工具技术,2007,41(6):25-32.
[20]张文毓.硬质合金涂层刀具研究进展[J].稀有金属与硬质合金,2008,36(1):59-63.
[21]沈中,刘钢,陈明.新型AlTiN涂层钻头高效干式钻削40Cr的开发与试验[J].南京航空航天大学学报(英文版),2007,24(2):106-111.
[22]郭幼丹.TiAlN涂层刀具高速铣削淬硬模具钢时磨损规律与寿命的研究[J].工具技术,2009,43(8):20-24.
[23]祝新发,张晶晶,周颐辛,等.离子镀TiAlN工具涂层的微结构与切削性能[J].工具技术,2010,44(12):31-34.
[24]Arias D, Devia A, Velez J. Study of TiN/ZrN/TiN/ZrN multilayers coatings grown by cathodic arc technique [J]. Surface and Coatings Technology,2010,204(18-19):2999-3003.
[25]Atar E, Kayali E S, Cimenoglu H. Sliding wear behaviour of ZrN and (Zr,12wt% Hf)N coatings [J]. Tribology International,2006,39(4):297-302.
[26]Huang M D, Lee Y P, Dong C, et al. Preparation of TiN films by arc ion plating using dc and pulsed biases [J]. Journal of Vacuum Science & Technology A,2004,22(2):250-254.
[27]Hainsworth S V, Soh W C. The effect of the substrate on the mechanical properties of TiN coatings [J]. Surface and Coatings Technology,2003,163-164:515-520.
[28]刘建华,邓建新,赵金龙,等.ZrN/TiN复合涂层刀具的制备及其磨损性能研究[J].制造技术与机床,2006,(11):25-27.
[29]刘建华,张卧波,邓建新,等.ZrN/TiN复合涂层刀具的制备及切削性能[J].山东大学学报(工学版),2006,36(6):14-18.
[30]邓建新,钮平章,王景海,等.“软”涂层刀具的发展与应用[J].工具技术,2005,39(3): 10-12.
[31]赵金龙,邓建新,宋文龙.MoS2软涂层刀具的基体材料优选及涂层制备[J].材料工程,2007,(12):30-34.
[32]赵金龙,邓建新,颜培MoS2/Zr复合涂层高速钢刀具的切削性能研究[J].中国机械工程,2008,19(21):2524-2527.
[33]李劲夫.涂层刀具推动数控加工发展[J].新技术新工艺,2009,(4):17-19.
[34]Okada M, Hosokawa A, Tanaka R, et al. Cutting performance of PVD-coated carbide and CBN tools in hardmilling [J]. International Journal of Machine Tools and Manufacture,2011, 51(2):127-132.
[35]Devillez A, Schneider F, Dominiak S, et al. Cutting forces and wear in dry machining of Inconel 718 with coated carbide tools [J]. Wear,2007,262(7-8):931-942.
[36]Schulz H, Dorr J, Rass I J, et al. Performance of oxide PVD-coatings in dry cutting operations [J]. Surface and Coatings Technology,2001,146-147:480-485.
[37]张迎光,白雪峰,张洪林,等.化学气相沉积技术的进展[J].中国科技信息,2005,(12):82-84.
[38]杨西,杨玉华.化学气相沉积技术的研究与应用进展[J].甘肃水利水电技术,2008,44(3):211-213.
[39]黎宪宽,陈力,蔡宏中,等.化学气相沉积技术及在难熔金属材料中的应用[J].稀有金属材料与[程,2010,39(z1):438-443.
[40]夏伯雄.刀具镀层的技术进展[J].理化检验-物理分册,2002,38(7):303-305.
[41]赵海波.国内外切削刀具涂层技术发展综述[J].工具技术,2002,(2):3-7.
[42]邓福铭,卢学军,赵志岩,等.CVD金刚石厚膜刀具及应用研究[M].2009中国超硬材料行业技术发展论坛论文集,2009.
[43]李健,韦习成.物理气相沉积技术的新进展[J].材料保护,2000,33(1):91-94.
[44]吴笛.物理气相沉积技术的研究进展与应用[J].机械工程与自动化,2011,(4):214-216.
[45]胡树兵,崔崑.物理气相沉积TiN多元涂层和多层涂层的研究进展[J].材料保护,2001,34(10):24-27.
[46]张洪涛,王天民,王聪.物理气相沉积技术制备的硬质涂层耐腐蚀的研究进展[J].材料 导报,2002,16(8):15-16.
[47]刘齐成,刘培英,陶冶,等.CVD法与PCVD法TiN薄膜研究[J].材料工程,2000,(12):22-25.
[48]吴昊.弧增强PCVD法设备及薄膜制备研究[D].北京航空航天大学硕士学位论文,2001.
[49]朱永法,张利,姚文清,等.溶胶-凝胶法制备薄膜型TiO2光催化剂[J].催化学报,1999,20(3):362-364.
[50]黄英,黄飞,王艳丽.溶胶-凝胶法制备纳米钡铁氧体薄膜[J].稀有金属材料与工程,2008,37(7):1229-1232.
[51]陈吉利,赵立峰,许加阳,等.高分子辅助溶胶-凝胶法制备BiFe1-xCoxO3薄膜及其性能[J].稀有金属材料与工程,2010,39(9):1668-1671.
[52]栗卓新,方建筠,魏琪,等.国内外热喷涂涂层形成机理的研究进展[J].中国机械工程,2006,17(11):1198-1203.
[53]王卫泽,李长久.热喷涂涂层的结构及其表征[J].材料保护,2006,39(11):43-47.
[54]侯国梁,周惠娣,安宇龙,等.铝合金异形曲面热喷涂涂层的制备及性能研究[J].表面技术,2010,39(3):67-70.
[55]罗乐,储雅琼,秦娟娟,等.用脉冲激光沉积法在A1203上沉积类金刚石薄膜[J].红外与激光工程,2011,40(6):1106-1110.
[56]刘红飞,程晓农,张志萍.脉冲激光沉积法制备ZrW2O8薄膜[J].硅酸盐学报,2009,37(5):755-759.
[57]张亦文,李效民,赵俊亮,等.脉冲激光沉积法生长In掺杂SrTiO3薄膜及其微观结构研究[J].无机材料学报,2008,23(3):531-534.
[58]刘耀东,赵磊.脉冲激光沉积法制备氧化锌薄膜[J].中国激光,2007,34(4):534-537.
[59]张桂凯,李炬,陈长安,等.HR-2不锈钢室温熔盐镀铝[J].稀有金属材料与工程,2010,39(7):1219-1223.
[60]王吉会,夏扬,王茂范.无机熔盐镀铝层的制备与性能研究[J].兵器材料科学与工程,2005,29(6):1-4.
[61]马瑞新,李国勋.熔盐镀钨的历史与发展趋势[J].材料保护,1999,32(2):4-6.
[62]蒋洪川,张金平,张万里,等.电镀法制备CoNiMnP永磁薄膜阵列的研究[J].无机材料 学报,2003,18(5):1143-1146.
[63]陈书荣,谢刚,张雄飞,等.NaCl-KCl熔融体系电镀钛的研究[J].稀有金属材料与工程,2001,30(6):471-474.
[64]林金堵,吴梅珠.化学镍/化学钯/浸金的表面涂覆层的可焊性和可靠性[J].印制电路信息,2011,(5):43-48.
[65]华中胜,姚广春,曹卓坤,等.碳纤维表面化学涂覆NiO[J].过程工程学报,2009,9(3):580-585.
[66]徐新乐.多弧离子镀用于制备高质量的Ti-N膜[J].材料保护,2000,33(8):28-30.
[67]姜雪峰,刘清才,王海波.多弧离子镀技术及其应用[J].重庆大学学报(自然科学版),2006,29(10):55-57.
[68]黄承敏.等离子浸没注入和多弧离子镀对纯钛及钛合金表面改性的基础研究[D].四川大学博士学位论文,2004.
[69]赵彦辉.脉冲偏压电弧离子镀沉积超硬多层薄膜[D].大连理工大学博士学位论文,2005.
[70]王利,程鑫彬,王占山,等.离子束辅助沉积薄膜工艺[J].红外与激光工程,2007,36(6):896-898.
[71]孙方宏,陈明,张志明,等.高性能CVD金刚石薄膜涂层刀具的制备和试验研究[J].机械工程学报,2003,39(7):101-106.
[72]黄树涛,许立福,姚英学,等.金刚石薄膜涂层刀具的破损机理研究[J].人工晶体学报,2004,33(2):278-281.
[73]宋贵宏,杜吴,贺春林.硬质与超硬涂层:结构、性能、制备与表征[M].北京:化学工业出版社,2007.
[74]Silva E, Rebelo de F M, Franz R, et al. Structure-property relations in ZrCN coatings for tribological applications [J]. Surface and Coatings Technology,2010,205(7):2134-2141.
[75]Ospina-Ospina R, Jurado J F, Velez J M, et al. Structural and morphological characterization WCxNy thin films grown by pulsed vacuum arc discharge in an argon-nitrogen atmosphere [J]. Surface and Coatings Technology,2010,205(7):2191-2196.
[76]Lin J, Moore J J, Moerbe W C, et al. Structure and properties of selected (Cr-Al-N, TiC-C, Cr-B-N) nanostructured tribological coatings [J]. International Journal of Refractory Metals and Hard Materials,2010,28(1):2-14.
[77]Garcia J, Pitonak R, Weissenbacher R, et al. Production and characterization of wear resistant Ti(C,N) coatings manufactured by modified chemical vapor deposition process [J]. Surface and Coatings Technology.2010,205(7):2322-2327.
[78]Zou D, Yan D, Xiao L, et al. Characterization of nanostructured TiN coatings fabricated by reactive plasma spraying [J]. Surface and Coatings Technology,2008,202(10):1928-1934.
[79]Yang Q, Wang C B, Zhang S, et al. Effect of nitrogen pressure on structure and optical properties of pulsed laser deposited BCN thin films [J]. Surface and Coatings Technology, 2010,204(11):1863-1867.
[80]Mannan M A, Noguchi H, Kida T, et al. Chemical bonding states and local structures of the oriented hexagonal BCN films synthesized by microwave plasma CVD [J]. Materials Science in Semiconductor Processing,2008,11(3):100-105.
[81]Yamamoto K, Ito H, Kujime S. Nano-multilayered CrN/BCN coating for anti-wear and low friction applications [J]. Surface and Coatings Technology,2007,201(9-11):5244-5248.
[82]Pi-Chuen T. The deposition and characterization of BCN films by cathodic arc plasma evaporation [J]. Surface and Coatings Technology,2007,201(9-11):5108-5113.
[83]Zhou F, Adachi K, Kato K. Friction and wear behavior of BCN coatings sliding against ceramic and steel balls in various environments [J]. Wear,2006,261(3-4):301-310.
[84]Tang Y, Li Y S, Yang Q, et al. Deposition and characterization of diamond coatings on WC-Co cutting tools with W/Al interlayer [J]. Diamond and Related Materials,2010,19(5-6): 496-499.
[85]Jian X G, Shi L D, Chen M, et al. Tribological studies on ultra-fine diamond composite coatings deposited on tungsten carbide [J]. Diamond and Related Materials,2006,15(2-3): 313-316.
[86]Vladimir I G. Characterization of cascade arc assisted CVD diamond-coating technology:Part Ⅱ. Coating properties and applications [J]. Surface and Coatings Technology,2005,194(2-3): 300-318.
[87]Burkat G K, Fujimura T, Dolmatov V Y, et al. Preparation of composite electrochemical nickel-diamond and iron-diamond coatings in the presence of detonation synthesis nanodiamonds [J]. Diamond and Related Materials,2005,14(11-12):1761-1764.
[88]Tzeng Y, Liu C, Hirata A. Effects of oxygen and hydrogen on electron field emission from microwave plasma chemically vapor deposited microcrystalline diamond, nanocrystalline diamond, and glassy carbon coatings [J]. Diamond and Related Materials,2003,12(3-7): 456-463.
[89]Lewis O D, Critchlow G W, Wilcox G D, et al. A study of the corrosion resistance of a waterborne acrylic coating modified with nano-sized titanium dioxide [J]. Progress in Organic Coatings,2012,73(1):88-94.
[90]Klocke F, Bouzakis K D, Georgiadis K, et al. Adhesive interlayers' effect on the entire structure strength of glass molding tools' Pt-Ir coatings by nano-tests determined [J]. Surface and Coatings Technology,2011,206(7):1867-1872.
[91]Bouzakis K. D, Gerardis S, Skordaris G, et al. Nano-impact test on a TiAIN PVD coating and correlation between experimental and FEM results [J]. Surface and Coatings Technology,2011, 206(7):1936-1940.
[92]Fox-Rabinovich G S, Yamamoto K, Aguirre M H, et al. Multi-functional nano-multilayered AlTiN/Cu PVD coating for machining of Inconel 718 superalloy [J]. Surface and Coatings Technology,2010,204(15):2465-2471.
[93]Ananda Kumar S, Sasikumar A. Studies on novel silicone/phosphorus/sulphur containing nano-hybrid epoxy anticorrosive and antifouling coatings [J]. Progress in Organic Coatings, 2010,68(3):189-200.
[94]韩敏建.刀具表面涂层技术的研究进展[J].兰州工业高等专科学校学报,2010,17(3):48-52.
[95]刘海浪,羊建高,黄如愿.硬质合金涂层刀具研究进展[J].凿岩机械气动工具,2009,(2):52-59.
[96]刘海浪,羊建高,黄如愿.硬质合金涂层刀具研究进展[M].第十四届全国钎钢钎具年会论文集,2008.
[97]王核源,王敬华.TiN涂层高速钢刀具的磨损特性及磨损规律[J].工具技术,1999,33(4):10-12.
[98]Deng J X, Liu J H, Ding Z L, et al. Unlubricated friction and wear behaviors of ZrN coatings against hardened steel [J]. Materials & Design,2008,29(9):1828-1834.
[99]Zhang J J, Wang M X, Yang J, et al. Enhancing mechanical and tribological performance of multilayered CrN/ZrN coatings [J]. Surface and Coatings Technology,2007,201(9-11): 5186-5189.
[100]Liu C, Lin G, Yang D, et al. In vitro corrosion behavior of multilayered Ti/TiN coating on biomedical AlSI 316L stainless steel [J]. Surface and Coatings Technology,2006,200(12-13): 4011-4016.
[101]Nordin M, Larsson M. Deposition and characterisation of multilayered PVD TiN/CrN coatings on cemented carbide [J]. Surface and Coatings Technology,1999,116-119:108-115.
[102]蔡志海,张平,谭俊,等.CrTiAIN复合涂层硬质合金刀具的制备与切削性能研究[J].核技术,2009,32(3):202-205.
[103]李佳,陈利,王社权TiAlSiN多元PVD涂层的研究[J].硬质合金,2010,27(5):263-268.
[104]钟平,孙方宏TiAlN涂层铣刀铣削9SiCr切削性能试验研究[J].现代制造工程,2005,(2):91-92.
[105]刘建华,邓建新,张庆余TiAlN涂层刀具的发展与应用[J].工具技术,2006,40(4):9-13.
[106]毛延发,唐为国,刘金良,等TiAlN纳米复合涂层的技术进展[J].工具技术,2006,40(4):20-24.
[107]Wang Q, Zhou F, Chen K, et al. Friction and wear properties of TiCN coatings sliding against SiC and steel balls in air and water [J]. Thin Solid Films,2011,519(15):4830-4841.
[108]Luo Q. Temperature dependent friction and wear of magnetron sputtered coating TiAIN/VN [J]. Wear,2011,271(9-10):2058-2066.
[109]Munteanu D, Gabor C, Constantin D G, et al. Friction and wear behaviours of Ti(C,O,N) dark decorative coatings [J]. Tribology International,2011,44(7-8):820-828.
[110]Ouyang J H, Sasaki S. The friction and wear characteristics of cathodic arc ion-plated (V,Ti)N coatings in sliding against alumina ball [J]. Wear,2004,257(7-8):708-720.
[111]Huang S H, Chen S F, Kuo Y C, et al. Mechanical and tribological properties evaluation of cathodic arc deposited CrN/ZrN multilayer coatings [J]. Surface and Coatings Technology, 2011,206(7):1744-1752.
[112]Chen L, Wang S Q, Zhou S Z, et al. Microstructure and mechanical properties of Ti(C,N) and TiN/Ti(C,N) multilayer PVD coatings [J]. International Journal of Refractory Metals and Hard Materials,2008,26(5):456-460.
[113]Lin Y W, Huang J H, Yu G P. Microstructure and corrosion resistance of nanocrystalline TiZrN films on AIS1 304 stainless steel substrate [J]. Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films,2010,28(4):774-778.
[114]Zhang S, Sun D, Fu Y, et al. Recent advances of superhard nanocomposite coatings:a review [J]. Surface and Coatings Technology,2003,167(2-3):113-119.
[115]Lang F, Yu Z. The corrosion resistance and wear resistance of thick TiN coatings deposited by arc ion plating [J]. Surface and Coatings Technology,2001,145(1-3):80-87.
[116]Choi I S, Park J C. The corrosion behavior of TiAIN coatings prepared by PVD in a hydrofluoric gas atmosphere [J]. Surface and Coatings Technology,2000,131(1-3):383-385.
[117]曹华伟,张程煜,乔生儒,等.物理气相沉积TiAIN涂层的研究进展[J].材料导报,2011,25(11):25-29.
[118]张飞,闫鹏勋,陈江涛,等.(Ti1-xAlx)N硬质涂层的研究进展[J].人工晶体学报,2007,36(3):699-704.
[119]高玉周,史雅琴,林国强,等.(Ti,Zr)N复合薄膜的微观结构及性能[J].大连海事大学学报,2002,28(2):81-84.
[120]黄佳木,徐成俊,王亚平.室温磁控溅射制备(Ti,Zr)N薄膜及其性能研究[J].材料科学与工程学报,2005,23(5):517-520.
[121]肖宏清,刘谦.空心阴极离子镀(Ti,Zr)N膜层制备及应用研究[J].表面技术,2004,33(6):57-59.
[122]Lin Y W, Huang J H, Yu G P. Effect of nitrogen flow rate on properties of nanostructured TiZrN thin films produced by radio frequency magnetron sputtering [J]. Thin Solid Films, 2010,518(24):7308-7311.
[123]Hoerling A, Sjolen J, Willmann H, et al. Thermal stability, microstructure and mechanical properties of Ti1-xZrxN thin films [J]. Thin Solid Films,2008,516(18):6421-6431.
[124]Niu E W, Li L, Lv G H, et al. Characterization of Ti-Zr-N films deposited by cathodic vacuum arc with different substrate bias [J]. Applied Surface Science,2008,254(13):3909-3914.
[125]Milosev I, Strehblow H H, Navinsek B. Oxidation of ternary TiZrN hard coatings studied by XPS [J]. Surface and Interface Analysis,1998,26(4):242-248.
[126]Zhang T H, Wu Y G, Zhao Z Y, et al. The ternary Ti (Zr,N) phases formation and modification of TiN coatings by Zr+ MEVVA ion implantation [J]. Surface and Coatings Technology,2000, 131(1-3):326-329.
[127]Uglov V V, Rusalski D P, Zlotski S V, et al. Stability of Ti-Zr-N coatings under Xe-ion irradiation [J]. Surface and Coatings Technology,2010,204(12-13):2095-2098.
[128]Uglov V V, Anishchik V M, Zlotski S V, et al. Structural and mechanical stability upon annealing of arc-deposited Ti-Zr-N coatings [J]. Surface and Coatings Technology,2008, 202(11):2394-2398.
[129]Uglov V V, Anishchik V M, Zlotski S V, et al. The phase composition and stress development in ternary Ti-Zr-N coatings grown by vacuum arc with combining of plasma flows [J]. Surface and Coatings Technology,2006,200(22-23):6389-6394.
[130]Uglov V V, Anishchik V M, Khodasevich V V, et al. Structural characterization and mechanical properties of Ti-Zr-N coatings, deposited by vacuum arc [J]. Surface and Coatings Technology,2004,180-181:519-525.
[131]Wang D Y, Chang C L, Hsu C H, et al. Synthesis of (Ti,Zr)N hard coatings by unbalanced magnetron sputtering [J]. Surface and Coatings Technology,2000,130(1):64-68.
[132]Donohue L A, Cawley J, Brooks J S. Deposition and characterisation of arc-bond sputter TixZryN coatings from pure metallic and segmented targets [J]. Surface and Coatings Technology,1995,72(1-2):128-138.
[133]Takeyama M B, Itoi T, Aoyagi E, et al. Diffusion barrier properties of nano-crystalline TiZrN films in Cu/Si contact systems [J]. Applied Surface Science,2003,216(1-4):181-186.
[134]Ramana J V, Kumar S, David C, et al. Structure, composition and microhardness of (Ti,Zr)N and (Ti,Al)N coatings prepared by DC magnetron sputtering [J]. Materials Letters,2004, 58(20):2553-2558.
[135]Purushotham K P, Ward L P, Brack N, et al. The effect of MEVVA ion implantation of Zr on the corrosion behaviour of PVD TiN coatings [J]. Corrosion Science,2008,50(1):8-14.
[136]Panjan P, Navinsek B, Cvelbar A, et al. Oxidation of TiN, ZrN, TiZrN, CrN, TiCrN and TiN/CrN multilayer hard coatings reactively sputtered at low temperature [J]. Thin Solid Films, 1996,281-282(1-2):298-301.
[137]马建丽.无机材料科学基础[M].重庆:重庆大学出版社,2008.
[138]Shannon R. Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides [J]. Acta Crystallographica Section A,1976,32(5):751-767.
[139]Pruymboom A, Kes P H, van der Drift E, et al. Flux-line shear through narrow constraints in superconducting films [J]. Physical Review Letters,1988,60(14):1430-1433.
[140]Denton A R, Ashcroft N W. Vegard's law [J]. Physical Review A,1991,43(6):3161-3164.
[141]李树棠.晶体X射线衍射线基础[M].北京:冶金工业出版社,1990.
[142]Niels H. Hall-Petch relation and boundary strengthening [J]. Scripta Materialia,2004,51(8): 801-806.
[143]Schiotz J, Vegge T, Di Tolla F D, et al. Atomic-scale simulations of the mechanical deformation of nanocrystalline metals [J]. Physical Review B,1999,60(17):11971-11983.
[144]Patterson A L. The Scherrer formula for X-Ray particle size determination [J]. Physical Review,1939,56(10):978-982.
[145]Schiotz J. Proceedings of the 22nd riso international symposium materials science [C]. Roskilde, Denmark,2001:127.
[146]Durupthy O, Bill J, Aldinger F. Bioinspired synthesis of crystalline TiO2:effect of amino acids on nanoparticles structure and shape [J]. Crystal Growth & Design,2007,7(12):2696-2704.
[147]叶大伦,胡建华.实用无机物热力学手册.第二版.[M].北京:冶金工业出版社,2002.
[148]Suresh S, Mortensen A.功能梯度材料基础[M].北京:国防工业出版社,2000.
[149]黄锡森.金属真空表面强化的原理与应用[M].上海:上海交通大学出版社,1989.
[150]张九渊.表面工程与失效分析[M].杭州:浙江大学出版社,2005.
[151]刘孝敏.工程材料的微观结构和力学性能[M].合肥:中国科学技术大学出版社,2003.
[152]李恒德,肖纪美.涂层表面与界面[M].北京:清华大学出版社,1990.
[153]波特J M,杜K N,迈耶J W.薄膜的相互扩散和反应[M].北京:国防工业出版社,1983.
[154]曹美蓉,魏仕勇,刘建军.物理气相沉积TiN涂层结合力的研究现状与展望[J].热处理技术与装备,2009,30(4):27-29.
[155]胡树兵,李志章,崔崑.过渡层对TiN涂层结合力的影响[J].材料保护,2001,34(9):1-3.
[156]肖国珍,黄春良.改善离子镀氮化钛涂层结合力的探索[C].98全国材料表面与界面的科学与工程研讨会论文摘要集.1998.
[157]Freund L B, Syresh S. Thin film materials-stress, defect formation and surface evolution [M]. Cambridge:Cambridge University Press,2003.
[158]Tsui Y C, Clyne T W. An analytical model for predicting residual stresses in progressively deposited coatings Part 1:Planar geometry [J]. Thin Solid Films,1997,306(1):23-33.
[159]Stoney G G. The tension of metallic films deposited by electrolysis [J]. Proceedings of the Royal Society of London Series A, Containing Papers of a Mathematical and Physical Character,1909,82(553):172-175.
[160]Nibennaoune Z, George D, Ahzi S, et al. Numerical simulation of residual stresses in diamond coating on Ti-6A1-4V substrate [J]. Thin Solid Films,2010,518(12):3260-3266.
[161]Chawla V, Jayaganthan R, Chandra R. Finite element analysis of thermal stress in magnetron sputtered Ti coating [J]. Journal of Materials Processing Technology,2008,200(1-3):205-211.
[162]Bialas M. Finite element analysis of stress distribution in thermal barrier coatings [J]. Surface and Coatings Technology,2008,202(24):6002-6010.
[163]Yilbas B S, Arif A F M. Residual stress analysis for hvof diamalloy 1005 coating on Ti-6A1-4V alloy [J]. Surface and Coatings Technology,2007,202(3):559-568.
[164]Julfikar H, Mahfujur R, Brian C, et al. Simulation of thermal stress in magnetron sputtered thin coating by finite element analysis [J]. Journal of Materials Processing Technology,2005, 168(1):36-41.
[165]Widjaja S, Limarga A M, Yip T H. Modeling of residual stresses in a plasma-sprayed zirconia/alumina functionally graded-thermal barrier coating [J]. Thin Solid Films,2003, 434(1-2):216-227.