Designing multilayer diamond like carbon coatings for improved mechanical properties

doi:10.1016/j.jmst.2020.04.077

Abstract

Abstract:

New multilayer coatings were produced by incorporating alternating soft and hard DLC layers enabled by varying the bias voltage during deposition process while maintaining a constant hard-to-soft layer thickness ratio. These coatings were deposited onto a Cr/CrC_x graded layer by closed field unbalanced magnetron sputtering (CFUBMS). The cross-sectional analysis of the coatings showed that the multilayer coatings possess sharp interfaces between the soft and hard layers with the hard to soft layer thickness ratio (1:1.33) constant in all the coatings. Raman analysis uncovered the increasing sp³ character of the DLC coatings as a result of decreasing I_D/I_G ratio and increasing full width at half maximum (FWHM) values of the G band peak induced supposedly by an increase in bias voltage during hard layer deposition. Nanoindentation tests showed an increase in hardness of the DLC coatings which can be correlated with the increase in the sp³ content of the coatings as well as decreasing sp²-C cluster size, as calculated from the I_D/I_G ratio. Furthermore, the coatings exhibited excellent plastic deformation resistance and adhesion strength upon microindentation and scratch testing, respectively. Although further investigations are required to assess coating durability, the multilayer design could offer the DLC coatings with a rare opportunity to combine the high hardness with damage resistance with a constant bilayer thickness and without the need to introduce complex multilayer system.

Key words: Diamond like carbon (DLC), Closed field unbalanced magnetron, sputtering (CFUBMS), sp³ Character, Nanoindentation, Plastic deformation resistance, Scratch adhesion behaviour

Mohammad Sharear Kabir, Zhifeng Zhou, Zonghan Xie, Paul Munroe. Designing multilayer diamond like carbon coatings for improved mechanical properties[J]. J. Mater. Sci. Technol., 2021, 65: 108-117.

Figures/Tables 11

Fig. 1. 2D architecture of the multilayer coating system.

Fig. 2. (a) Ion induced SE micrograph of coating DLC-1, (b) XTEM bright field micrograph of coating DLC-4 (insert shows SAED pattern from the DLC multilayer. (c) XTEM bright field micrograph of coating DLC-4 showing the CrCx graded layer together with the Cr adhesive layer adjacent to the substrate.

Fig. 3. XTEM EDS linescan of the Cr adhesive layer and the CrCx graded layer in DLC-4 coating (length of arrow =600 nm).

Fig. 4. Three-dimensional surface topography of DLC coatings in a 10 μm x 10 μm area as determined by contact mode AFM.

Fig. 5. TOF-SIMS depth profile for coating DLC-4.

Fig. 6. Raman analysis of the DLC coatings: (a) Visible Raman spectra of DLC coatings, (b) Gaussian fitting of the raw data and deconvolution into G peak and D peak [48].

Fig. 7. (a) FWHM of the G peak of as a function of negative bias voltage, (b) sp3 content vs FWHM(G) of DLC samples (quadratic fitting is shown as the red line) and (c) ID/IG ratio and graphite cluster size with respect to increasing negative bias voltage.

Fig. 8. (a) P vs h curves (load = 15 mN), (b) Hardness and (c) Modulus as a function of bias voltage, (d) Elastic strain to failure (H/E) (diamonds) and plastic deformation resistance (H3/E2) (stars) with respect to increasing bias voltage.

Fig. 9. 3D laser-confocal micrographs of Berkovich indents produced at an indentation load of 200 mN.

Fig. 10. Acoustic emission (AE) signal corresponding to friction force (Ft) curve of DLC-4 coating.

Fig. 11. Back scattered electron micrographs of scratch tracks of all DLC coatings.

References 62

[1]	M. Jelinek, T. Kocourek, J. Zemek, J. Mikšovský, Š. Kubinová, J. Remsa, J. Kopeček, K. Jurek, Mater. Sci. Eng. C 46 (2015) 381-386. DOI URL
[2]	E.L. Dalibón, D. Heim, C. Forsich, A. Rosenkranz, M. Agustina Guitar, S.P. Brühl, Diam. Relat. Mater. 59 (2015) 73-79. DOI URL
[3]	Y. Iijima, T. Harigai, R. Isono, S. Degai, T. Tanimoto, Y. Suda, H. Takikawa, H. Yasui, S. Kaneko, S. Kunitsugu, M. Kamiya, M. Taki, AIP Conf. Proc. 1929 (2018) 020024.
[4]	F. Li, S. Zhang, J. Kong, Y. Zhang, W. Zhang, Thin Solid Films 519 (2011) 4910-4916. DOI URL
[5]	J. Robertson, Thin Solid Films 383 (2001) 81-88. DOI URL
[6]	D. Franta, V. Burˇsíková, I. Ohlídal, L. Zajíˇcková, P. St_ahel, Diam.Relat. Mater. 14 (2005) 1795-1798.
[7]	A.W. Zia, S. Lee, J.-k. Kim, T.G. Kim, J. Song II, Surf. Interface Anal. 46 (2014) 152-156. DOI URL
[8]	C. Guo, Z. Pei, J. Gong, C. Sun, S. Lin, Q. Shi, Diam. Relat. Mater. 92 (2019) 187-197. DOI URL
[9]	Y. Lin, Z. Zhou, K.Y. Li, Appl. Surf. Sci. 477 (2019) 137-146. DOI URL
[10]	X. Sui, J. Liu, S. Zhang, J. Yang, J. Hao, Appl. Surf. Sci. 439 (2018) 24-32. DOI URL
[11]	D. Batory, T. Blaszczyk, M. Clapa, S. Mitura, J. Mater. Sci. 43 (2008) 3385-3391. DOI URL
[12]	D. Bociaga, P. Komorowski, D. Batory, W. Szymanski, A. Olejnik, K. Jastrzebski, W. Jakubowski, Appl. Surf. Sci. 355 (2015) 388-397. DOI URL
[13]	R. Hauert, K. Thorwarth, G. Thorwarth, Surf. Coat. Technol. 233 (2013) 119-130. DOI URL
[14]	B.J. Jones, A. Mahendran, A.W. Anson, A.J. Reynolds, R. Bulpett, J. Franks, Diam. Relat. Mater. 19 (2010) 685-689. DOI URL
[15]	C.A. Love, R.B. Cook, T.J. Harvey, P.A. Dearnley, R.J.K. Wood, Tribol. Int. 63 (2013) 141-150. DOI URL
[16]	A. Erdemir, C. Donnet, J. Phys. D Appl. Phys.. 39 (2006) R311-R327. DOI URL
[17]	Y. Lin, A.W. Zia, Z. Zhou, P.W. Shum, K.Y. Li, Surf. Coat. Technol. 320 (2017) 7-12. DOI URL
[18]	D. Sheeja, B.K. Tay, S.P. Lau, X. Shi, X. Ding, Surf. Coat. Technol. 132 (2000) 228-232. DOI URL
[19]	A.A. Voevodin, M.S. Donley, J.S. Zabinski, J.E. Bultman, Surf. Coat. Technol. 76-77 (1995) 534-539. DOI URL
[20]	A.A. Voevodin, S.D. Walck, J.S. Zabinski, Wear 203-204 (1997) 516-527. DOI URL
[21]	S. Zhang, X. Lam Bui, X.T. Zeng, X. Li, Thin Solid Films 482 (2005) 138-144. DOI URL
[22]	Y.S. Zou, K. Zhou, Y.F. Wu, H. Yang, K. Cang, G.H. Song, Vacuum 86 (2012) 1141-1146. DOI URL
[23]	A.G. Owens, S. Brühl, S. Simison, C. Forsich, D. Heim, Procedia Mater. Sci. 9 (2015) 246-253. DOI URL
[24]	C. Donnet, A. Erdemir, Tribology of Diamond-like Carbon Films: Fundamentals and Applications, Springer, US, 2007.
[25]	J. Chen, S.J. Bull, J. Phys. D Appl. Phys. 44 (2010) 034001. DOI URL
[26]	A.A. Voevodin, J.S. Zabinski, Diam. Relat. Mater. 7 (1998) 463-467. DOI URL
[27]	A.A. Voevodin, J.P. O’Neill, S.V. Prasad, J.S. Zabinski, J. Vacuum Sci. Technol. A 17 (1999) 986-992. DOI URL
[28]	F. Awaja, T.-T. Wong, D. Putzer, M. Thaler, A. al Taee, T. O’Brien, Mater. Today Commun. 19 (2019) 433-440.
[29]	W. Dai, X. Gao, J. Liu, S.-H. Kwon, Q. Wang, Appl. Surf. Sci. 425 (2017) 855-861. DOI URL
[30]	F.D. Duminica, R. Belchi, L. Libralesso, D. Mercier, Surf. Coat. Technol. 337 (2018) 396-403. DOI URL
[31]	L. Huang, J. Yuan, C. Li, D. Hong, Surf. Coat. Technol. 353 (2018) 163-170. DOI URL
[32]	N. Nemati, O.V. Penkov, D.-E. Kim, Surf.Coat. Technol. 385 (2020) 125446.
[33]	F.-e. Yang, S.-y. Yang, X.-x. Chang, W.-f. Yang, R.-g. Song, X.-h. Zheng, Surf. Coat. Technol. 374 (2019) 418-423. DOI URL
[34]	J.-B. Wu, M.-L. Lin, X. Cong, H.-N. Liu, P.-H. Tan, Chem. Soc. Rev. 47 (2018) 1822-1873. DOI URL PMID
[35]	A.C. Ferrari, J. Robertson, Phys. Rev. B 61 (2000) 14095-14107. DOI URL
[36]	T. Paulmier, J.M. Bell, P.M. Fredericks, Thin Solid Films 515 (2007) 2926-2934. DOI URL
[37]	B. Zhou, Z. Liu, D.G. Piliptsou, S. Yu, Z. Wang, A.V. Rogachev, A.S. Rudenkov, A. Balmakou, Diam. Relat. Mater. 69 (2016) 191-197. DOI URL
[38]	P. Binayak, Secondary Ion Mass Spectroscopy, ASM Handbook: Materials Characterization, ASM International, 2019.
[39]	J.M. Cairney, P.R. Munroe, M. Hoffman, Surf. Coat. Technol. 198 (2005) 165-168. DOI URL
[40]	W.C. Oliver, G.M. Pharr, J. Mater. Res. 7 (1992) 1564-1583. DOI URL
[41]	G.M. Pharr, W.C. Oliver, MRS Bull. 17 (1992) 28-33.
[42]	B.D. Beake, T.W. Liskiewicz, V.M. Vishnyakov, M.I. Davies, Surf. Coat. Technol. 284 (2015) 334-343. DOI URL
[43]	J.W. Patten, Thin Solid Films 63 (1979) 121-129. DOI URL
[44]	J. Robertson, Mater. Sci. Eng. R Rep. 37 (2002) 129-281. DOI URL
[45]	S. Logothetidis, M. Gioti, C. Charitidis, P. Patsalas, J. Arvanitidis, J. Stoemenos, Appl. Surf. Sci. 138-139 (1999) 244-249. DOI URL
[46]	J.C. Vickerman, D. Briggs, ToF-SIMS: Surface Analysis by Mass Spectrometry, IM, 2001.
[47]	I. Ahmad, P.D. Maguire, P. Lemoine, S.S. Roy, J.A. McLaughlin, Diam.Relat. Mater. 13 (2004) 1346-1349.
[48]	L.R. Shaginyan, Chapter 13 in: H. Singh Nalwa (Ed.), Handbook of Thin Films, Academic Press, Burlington, 2002, pp. 627-673.
[49]	F.C. Tai, S.C. Lee, J. Chen, C. Wei, S.H. Chang, J. Raman Spectrosc. 40 (2009) 1055-1059. DOI URL
[50]	A.C. Ferrari, S.E. Rodil, J. Robertson, Phys. Rev. B 67 (2003) 155306. DOI URL
[51]	W.G. Cui, Q.B. Lai, L. Zhang, F.M. Wang, Surf. Coat. Technol. 205 (2010) 1995-1999. DOI URL
[52]	A.C. Ferrari, Solid State Commun. 143 (2007) 47-57. DOI URL
[53]	B.K. Tay, X. Shi, H.S. Tan, D.H.C. Chua, Surf. Interface Anal. 28 (1999) 231-234. DOI URL
[54]	F. Tuinstra, J.L. Koenig, J. Chem. Phys. 53 (1970) 1126-1130.
[55]	X. Yu, M. Hua, C. Wang, J. Nanosci. Nanotechnol. 9 (2009) 6366-6371. DOI URL PMID
[56]	A. Leyland, A. Matthews, Wear 246 (2000) 1-11. DOI URL
[57]	S.J. Bull, E.G. Berasetegui, Tribol. Int. 39 (2006) 99-114. DOI URL
[58]	H. Ollendorf, D. Schneider, Surf. Coat. Technol. 113 (1999) 86-102. DOI URL
[59]	S.J. Bull, D.S. Rickerby, Surf. Coat. Technol. 42 (1990) 149-164. DOI URL
[60]	P.A. Steinmann, Y. Tardy, H.E. Hintermann, Thin Solid Films 154 (1987) 333-349. DOI URL
[61]	A. Herrmann, DLC Coating Failure Using Micro Scratch Testing, NANOVEA, Irvine, CA, USA, 2013.
[62]	P.J. Burnett, D.S. Rickerby, Thin Solid Films 154 (1987) 403-416. DOI URL