Corrosion and tribological properties of TiAlCN/TiAlN/TiAlcomposite system deposited by magneticfliter cathode vacuum arctechnique

Chen Shu-Nian; Liao Bin; Chen Lin; Zhang Zhi-Qiang; Shen Yong-Qing; Wang Hao-Qi; Pang Pan; Wu Xian-Ying; Hua Qing-Song; He Guang-Yu

doi:10.7498/aps.69.20200012

Abstract

The experiment is based on novel magnetic filtered cathodic vacuum arc (FCVA) technology, the effects of the structure and C contents of TiAlCN/TiAlN/TiAl composite coating on anticorrosion and wear resistance were studied. The macro/micro properties of the coatings were systematically characterized by SEM, XRD, XPS, electrochemical tests and friction equipment. The results show that, with the increase of C content,the form of C element in the coatings transforms from the TiAlCN solid solution to the coexistence of crystallized TiAlCN/amorphous carbon. The TiAlCN/TiAlN/TiAl coating with TiAlCNcrystallized/amorphous carbon nanocomposite structure demonstrated excellent performanceby combining the advantages of each layer, which the hardness reaches an ultrahigh leveland the amorphous carbonwith excellent self-lubricating effect exists in the coating structure. In 3.5% NaCl electrochemical corrosion test, E_corr increased by 5.6 times to 0.271 V, I_corr decreased by 1/52 to 8.092 ×10^–9 A·cm^–2. During the dry sliding, friction coefficient decreased by 1/3 to 0.43, and wear rate decreased by 1/1.4 to 1.13×10^–5 mm³·N^–1·m^–1.

Keywords:

TiAlCN/TiAlN/TiAlmultilayer composite coatings /
crystallized TiAlCN/amorphous carbon /
friction /
corrosion

Authors and contacts

1.
Key Laboratory of Beam Technology of Ministry of Education, College of Nuclear Science and Technology, Beijing Normal University, Beijing 100875, China
2.
Beijing Radiation Center, Beijing 100875, China
3.
Science and Technology on Plasma Dynamics Laboratory, Air Force Engineering University, Xi’an 710038, China

Corresponding author: Liao Bin, liaobingz@bnu.edu.cn

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References

[1]	王均涛, 刘平, 李伟, 郑康培 2010 热加工工艺 20 104 Google Scholar Wang J T, Liu P, Li W, Zheng K P 2010 Hot Working Technology 20 104 Google Scholar
[2]	PalDey S, Deevi S C 2003 Sci. Eng. A 342 58 Google Scholar
[3]	Hsu C H, Lee C Y, Lee C C 2009 Thin Solid Films 17 5212
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Cited By

图 1 FCVA沉积装置示意图

Figure 1. The schematic diagram of the FCVA deposition system.

DownLoad: Full-Size Img PowerPoint

图 2 涂层中各层分布

Figure 2. Distribution of the layers in the coating.

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图 3 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层的截面形貌　(a) 0 sccm; (b) 10 sccm; (c) 15 sccm

Figure 3. Thecrosssection of TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂:(a) 0 sccm; (b) 10 sccm; (c) 15 sccm

DownLoad: Full-Size Img PowerPoint

图 4 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层的XRD图谱

Figure 4. XRD diffractogram of TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂.

DownLoad: Full-Size Img PowerPoint

图 5 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层的拉曼谱图

Figure 5. Raman spectra of TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂.

DownLoad: Full-Size Img PowerPoint

图 6 S3(15 sccm, 12.39 at.%C)的XPS图谱　(a) N 1s; (b) C 1s; (c) Ti 2p; (d) Al 2p

Figure 6. XPS analysis of S3: (a) N 1s;(b) C 1s;(c) Ti 2p; (d) Al 2p.

DownLoad: Full-Size Img PowerPoint

图 7 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层在3.5 wt-% NaCl溶液中的动电位极化曲线

Figure 7. Potentiodynamic polarization curves of TiAlCN/TiAlN/TiAl coatings in 3.5 wt-% NaCl solution.

DownLoad: Full-Size Img PowerPoint

图 8 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层电化学腐蚀的数据结果

Figure 8. Results of Electrochemical corrosion characterization activities for TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂.

DownLoad: Full-Size Img PowerPoint

图 9 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层电化学阻抗谱

Figure 9. Electrochemical impedance spectroscopy of TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂.

DownLoad: Full-Size Img PowerPoint

图 10 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层的阻抗-频率图

Figure 10. Bode plots ofTiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂.

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图 11 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层的相角-频率图

Figure 11. Bode phase angle plots ofTiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂.

DownLoad: Full-Size Img PowerPoint

图 12 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层表面SEM形貌(a)0 sccm; (b)10 sccm; (c)15 sccm

Figure 12. SEM surface micrographs of TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂: (a)0 sccm; (b)10 sccm; (c)15 sccm.

DownLoad: Full-Size Img PowerPoint

图 13 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层的摩擦系数

Figure 13. Friction coefficient curves of TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂.

DownLoad: Full-Size Img PowerPoint

图 14 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层的摩擦系数和磨损率

Figure 14. Friction coefficientand wear rate of TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂.

DownLoad: Full-Size Img PowerPoint

图 15 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层磨痕区的SEM图像和EDS能谱分析　(a), (b) 0 sccm; (c), (d) 10 sccm; (e), (f) 15 sccm

Figure 15. SEM micrographs of the wear track and EDS results of TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂: (a), (b) 0 sccm; (c), (d) 10 sccm; (e), (f) 15 sccm.

DownLoad: Full-Size Img PowerPoint

图 16 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层磨痕处的拉曼谱图

Figure 16. Raman spectra of wear track of TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂.

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表 1 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层的元素相对含量

Table 1. Chemical composition of TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂.

Sample C₂H₂/sccm Ti/at.% Al/at.% N/at.% C/at.%

TiAlN/TiAl S1 0 30.87 22.85 46.28 —
TiAlCN/TiAlN/TiAl S2 10 28.64 21.52 41.23 8.61
TiAlCN/TiAlN/TiAl S3 15 27.60 22.95 37.07 12.39

DownLoad: CSV

表 2 不同C₂H₂流量沉积的TiAlCN/TiAlN/TiAl涂层的显微硬度、杨氏模量和H/E比值

Table 2. Microhardness、Modules and ratio of H/E of TiAlCN/TiAlN/TiAl coatings deposited at various C₂H₂.

Sample C₂H₂/sccm E/GPa H/GPa H/E

TiAlN/TiAl S1 0 290.20 30.53 0.105
TiAlCN/TiAlN/TiAl S2 10 310.65 41.16 0.133
TiAlCN/TiAlN/TiAl S3 15 316.14 44.36 0.140

DownLoad: CSV

[1]	王均涛, 刘平, 李伟, 郑康培 2010 热加工工艺 20 104 Google Scholar Wang J T, Liu P, Li W, Zheng K P 2010 Hot Working Technology 20 104 Google Scholar
[2]	PalDey S, Deevi S C 2003 Sci. Eng. A 342 58 Google Scholar
[3]	Hsu C H, Lee C Y, Lee C C 2009 Thin Solid Films 17 5212
[4]	Brogren M, Harding G L, Karmhag R, Ribbing C G, Niklasson G A, Stenmark L 2000 Thin Solid Films 370 268 Google Scholar
[5]	Hovsepian PEh, Münz W D, Medlock A, Gregory G 2000 Surf. Coat. Technol. 133–134 508
[6]	Warcholinski B, Gilewicz A 2011 Wear 271 2812 Google Scholar
[7]	Zheng J Y, Hao J Y, Li u X, Gong Q Y, Liu W M 2012 Surf. Coat. Technol. 209 110 Google Scholar
[8]	Agudelo L C, Ospina R, Castillo H A, Devia A 2008 Phys. Scr. T131 014006 Google Scholar
[9]	Kamath G, Ehiasarian A P, Purandare Y, Hovsepian PEh 2011 Surf. Coat. Technol. 205 2823 Google Scholar
[10]	Hovsepian PEh, Ehiasarian A P, Deeming A, Schimpf C 2008 Vacuum 82 1312 Google Scholar
[11]	Yang L J, Zhang Z H, Dang X A, Li L 2014 Mater. Sci. Forum 789 449 Google Scholar
[12]	AL-Bukhaiti M A, Al-hatab K A, Tillmann W, Hoffmann F, Sprute T 2014 Appl. Surf. Sci. 318 180 Google Scholar
[13]	Kawata K, Sugimura H, Takai O 2001 Thin Solid Films 390 64 Google Scholar
[14]	单磊, 王永欣, 李金龙 2013 中国表面工程 26 86 Google Scholar Shan L, Wang Y X, Li J L 2013 China Surface Engineering 26 86 Google Scholar
[15]	Kuptsov K A, Kiryukhantsev-Korneev P V, Sheveryko A N, ShtanskyDV 2013 Surf. Coat. Technol. 216 273 Google Scholar
[16]	李刘合, 张海泉, 崔旭明 2001 物理学报 08 1549 Google Scholar Li L H, Zhang H Q, Cui X M 2001 Acta Phys. Sin. 08 1549 Google Scholar
[17]	Ferrari A C, Kleinsorge B, Morrison N A, Hart A 1999 J. Appl. Phys. 857 191
[18]	Zhang X H, Jiang J Q, Zeng Y Q, Lin J L, Wang F L, Moore J J 2008 Surf. Coat. Technol. 203 594 Google Scholar
[19]	Zeng Y Q, Qiu Y D, Mao X Y, Tan X Y, Tan Z, Zhang X H, Chen J, Jiang J Q 2015 Thin Solid Films 584 283 Google Scholar
[20]	Dreiling I, Stiens D, Chasse T 2010 Surf. Coat. Technol. 205 1339 Google Scholar
[21]	Rodríguez R J, García J A, Medrano A, Rico M, Sánchez R, Martínez R, Labrugère C, Lahaye M, Guette A 2002 Vacuum 67 559 Google Scholar
[22]	段晋辉, 梁银, 裴旺, 杨喜昆 2016 金属热处理 41 139 Du J H, Liang Y, Pei W, Yang X K 2016 Heat Treatment of Metals 41 139
[23]	Jang C S, Jeon J H, Song P K, Kang M C, Kim K H 2005 Surf. Coat. Technol. 200 1501 Google Scholar
[24]	Zehnder T, Schwaller P, Munnik F, Mikhailov S, Patscheider J 2004 J. Appl. Phys 95 4327 Google Scholar
[25]	Matthews A, Franklin S, Holmberg K 2007 J. Phys. D: Appl. Phys. 40 5463 Google Scholar
[26]	Musil J, Jirout M 2007 Surf. Coat. Technol. 201 5148 Google Scholar
[27]	Massiani Y, Medjahed A, Crousier J P, Gravier P, Rebatel I 1991 Surf. Coat. Technol. 45 115 Google Scholar
[28]	陈淑年, 廖斌, 吴先映, 陈琳, 黄杰, 何光宇 2019 中国表面工程 3 49 Google Scholar Chen S N, Liao B, Wu X Y, Chen L, Huang J, He G Y 2019 China Surface Engineering 3 49 Google Scholar
[29]	Vacandio F, Massiani Y, Gravier P, Rossi S, Bonora P L, Fedrizzi L 2001 Electrochim. Acta 46 3827 Google Scholar
[30]	郑建云, 郝俊英, 刘小强, 龚秋雨, 刘维民 2013 摩擦学学报 33 87 Zheng J Y, Hao J Y, Liu X Q, Gong Q Y, Liu W M 2013 Tribology 33 87
[31]	Eriksson A O, Ghafoor N, Jensen J, Näslund L Å, Johansson M P, Sjölen J, Odén M, Hultman L, Rosen J 2012 Surf. Coat. Technol. 213 145 Google Scholar
[32]	Chen L, Yang B, Xu Y X, Pei F, Zhou L C, Du Y 2014 Thin Solid Films 556369
[33]	HoörlingA, Hultman L, Odén M, Sjölén J, Karlsson L 2002 J. Vac. Sci. Technol. A 20 1815
[34]	Cheng H H, Lee C Y, Lee C C 2009 ThinSolid Films 517 5212 Google Scholar
[35]	Xie Z W, Wang L P, Wang X F, Huang L, Lu Y, Yan J C 2011 Trans. Nonferrous Met. Soc. China 21 470 Google Scholar
[36]	Sampath Kumar T, Balasivanandha Prabu S, Manivasagam G 2014 J. Mater. Eng. Perform 23 2877 Google Scholar
[37]	王泓 2002 博士学位论文 (西安: 西北工业大学) Wang H 2002 Ph. D. Dissertation (Xian: Northwestern Polytechnical University) (in Chinese)

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