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Experimental Mechanics

Erschienen in:

01.07.2010

A Discontinuous Elastic Interface Transfer Model of Thin Film Nanoindentation

verfasst von: B. Zhou, B. C. Prorok

Erschienen in: Experimental Mechanics | Ausgabe 6/2010

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Abstract

A new model of thin film indentation that accounted for an apparent discontinuity in elastic strain transfer at the film/substrate interface was developed. Finite element analysis suggested that numerical values of strain were not directly continuous across the interface; the values in the film were higher when a soft film was deposited on a hard substrate. The new model was constructed based on this discontinuity; whereby, separate weighting factors were applied to account for the influence of the substrate in strain developed in the film and vice-versa. By comparing the model to experimental data from thirteen different amorphous thin film materials on a silicon substrate, constants in each weighting factor were found to have physical significance in being numerically similar to the bulk scale Poisson’s ratios of the materials involved. When employing these material properties in the new model it was found to provide an improved match to the experimental data over the existing Doerner and Nix and Gao models. Finally, the model was found to be capable of assessing the Young’s modulus of thin films that do not exhibit a flat region as long as the bulk Poisson’s ratio is known.

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Pethica JB, Hutchings R, Oliver WC (1983) Hardness measurement at penetration depths as small as 20 nm. Philos Mag A 48:593–606CrossRef

Doerner MF, Nix WD (1986) A method for interpreting data from depth-sensing indentation instruments. J Mater Res 1:601–609CrossRef

Gao H, Chiu C-H, Lee J (1992) Elastic Contact versus Indentation Modelling of Multi-Layered Materials. Int J Solids Structures 29:2471–2492CrossRef

Pharr GM, Callahan DL, McAdams SD, Tsui TY, Anders S, Anders A, Ager Iii JW, Brown IG, Bhatia CS, Silva SRP (1996) Hardness, elastic modulus, and structure of very hard carbon films produced by cathodic-arc deposition with substrate pulse biasing. Appl Phys Lett 68:779–781CrossRef

Chen X, Vlassak JJ (2001) Numerical study on the measurement of thin film mechanical properties by means of nanoindentation. J Mater Res 16:2974–2982CrossRef

King RB (1987) Elastic Analysis of Some Punch Problems for a Layered Medium. Int J Solids Struct 23:1657–1664MATHCrossRef

Nix WD (1989) Mechanical properties of thin films. Met Trans A 20:2217–2245CrossRef

Knapp JA, Follstaedt DM, Myers SM, Barbour JC, Friedmann TA (1999) Finite-element modeling of nanoindentation. J Appl Phys 85:1460–1474CrossRef

Buckle H (1973) The science of hardness testing and its research applications. ASM, Metals Park

10.

Ahn JH, Kwon D (2000) Micromechanical estimation of composite hardness using nanoindentation technique for thin-film coated system. Mater Sci Eng A 285:172–179CrossRef

11.

Bolshakov A, Pharr GM (1998) Influences of pileup on the measurement of mechanical properties by load and depth sensing indentation techniques. J Mater Res 13:1049–1058CrossRef

12.

Cho SJ, Lee KR, Eun KY, Hahn JH, Ko DH (1999) Determination of elastic modulus and poisson’s ratio of diamond-like carbon films. Thin Solid Films 341:207–210CrossRef

13.

Frohlich F, Grau P, Grellmann W (1977) Performance and Analysis of Recording Microhardness Tests. Phys Status Solid A 42:79–89CrossRef

14.

Huang Y, Aziz MJ, Hutchinson JW, Evans AG, Saha R, Nix WD (2001) Comparison of mechanical properties of Ni3Al thin films in disordered FCC and ordered L12 phases. Acta Mater 49:2853–2861CrossRef

15.

Li X, Bhushan B (2002) A review of nanoindentation continuous stiffness measurement technique and its applications. Mater Char 48:11–36CrossRef

16.

Li X, Diao D, Bhushan B (1997) Fracture mechanisms of thin amorphous carbon films in nanoindentation. Acta Mater 45:4453–4461CrossRef

17.

Li X, Gao H, Murphy CJ, Caswell KK (2003) Nanoindentation of Silver Nanowires. Nano Lett 3:1495–1498CrossRef

18.

Loubet JL, Georges JM, Marchesini O, Meille G (1984) Vickers indentation curves of magnesium oxide(MgO). J Lub Tech 106:43–48

19.

Mayo MJ, Siegel RW, Narayanasamy A, Nix WD (1990) Mechanical Properties of Nanophase TiO₂ as Determined by Nanoindentation. J Mater Res 5:1073–1082CrossRef

20.

McElhaney KW, Vlassak JJ, Nix WD (1998) Determination of indenter tip geometry and indentation contact area for depth-sensing indentation experiments. J Mater Res 13:1300–1306CrossRef

21.

Mencik J, Munz D, Quandt E, Weppelmann ER, Swain MV (1997) Determination of elastic modulus of thin layers using nanoindentation. J Mater Res 1997:2475–2484CrossRef

22.

Nix WD (1997) Elastic and plastic properties of thin films on substrates: nanoindentation techniques. Mater Sci Eng A 234:37–44CrossRef

23.

Nix WD, Gao H (1998) Indentation size effects in crystalline materials: A law for strain gradient plasticity. J Mech Phys Sol 46:411–425MATHCrossRef

24.

Nix WD, Greer JR, Feng G, Lilleodden ET (2007) Deformation at the nanometer and micrometer length scales: Effects of strain gradients and dislocation starvation. Thin Solid Films 515:3152–3157CrossRef

25.

Oliver WC (1986) Progress in the Development of a Mechanical Properties Microprobe. MRS Bull 11:15–19

26.

Oliver WC, Pharr GM (1992) Improved Technique for Determining Hardness and Elastic Modulus Using Load and Displacement Sensing Indentation Eexperiments. Journal of Materials Research 7:1564–1583CrossRef

27.

Pharr GM (1998) Measurement of mechanical properties by ultra-low load indentation. Mat Sci & Eng A 253:151–159CrossRef

28.

Randall NX, Harris A (2000) Nanoindentation as a tool for characterising the mechanical properties of tribological transfer films. Wear 245:196–203CrossRef

29.

Rho JY, Tsui TY, Pharr GM (1997) Elastic properties of human cortical and trabecular lamellar bone measured by nanoindentation. Biomater 18:1325–1330CrossRef

30.

Saha R, Nix WD (2002) Effects of the substrate on the determination of thin film mechanical properties by nanoindentation. Acta Mater 50:23–38CrossRef

31.

Saha R, Xue Z, Huang Y, Nix WD (2001) Indentation of a soft metal film on a hard substrate: strain gradient hardening effects. J Mech Phys Sol 49:1997–2014MATHCrossRef

32.

Swadener JG, Taljat B, Pharr GM (2001) Measurement of residual stress by load and depth sensing indentation with spherical indenters. J Mater Res 16:2091–2102CrossRef

33.

Tsui TY, Oliver WC, Pharr GM (1996) Influences of stress on the measurement of mechanical properties using nanoindentation: Part I. Experimental studies in an aluminum alloy. J Mater Res 11:752–759CrossRef

34.

Woirgard J, Dargenton JC (1997) An alternative method for penetration depth determination in nanoindentation measurements. J Mater Res 12:2455–2458CrossRef

35.

Zhou B, Prorok BC, Erdemir A, Eryilmaz O (2006) Annealing effects on the mechanical properties of near-frictionless carbon thin films. Diam Relat Mater 15:2051–2054CrossRef

36.

Zhou B, Wang L, Mehta N, Morshed S, Erdemir A, Eryilmaz O, Prorok BC (2006) The mechanical properties of freestanding near-frictionless carbon films relevant to MEMS. J Micromech Microeng 16:1374–1381CrossRef

37.

Nano Indenter XP, Agilent Technologies, http://www.agilentnano.com/

38.

Triboscope, Hysitron Inc., http://www.hysitron.com/

39.

UMIS-2000, CSIRO, http://www.csiro.au/

40.

Nano Hardness Tester, CSM Instruments, http://www.csm-instruments.com/

41.

Fischerscope, Helmut Fischer Gmbh, http://www.fischer-technology.com/home.html

42.

Pastorelli R, Ferrari AC, Beghi MG, Bottani CE, Robertson J (2000) Elastic constants of ultrathin diamond-like carbon films. Diam Relat Mater 9:825–830CrossRef

43.

Bhushan B, Li X (1997) Micromechanical and tribological characterization of doped single-crystal silicon and polysilicon films for microelectromechanical systems devices. J Mater Res 12:54–63CrossRef

44.

Wortman JJ, Evans RA (1965) Young’s Modulus, Shear Modulus, and Poisson’s Ratio in Silicon and Germanium. J Appl Phys 36:153–156CrossRef

45.

Stillwell NA, Tabor D (1961) Elastic Recovery of Conical Indentations. Proc R Soc 78:169CrossRef

46.

Erdemir A, Eryilmaz OL, Fenske G (2000) Synthesis of diamondlike carbon films with superlow friction and wear properties. J Vac Sci Tech A 18:1987–1992CrossRef

47.

Prorok BC, Espinosa HD (2002) Effects of nanometer-thick passivation layers on the mechanical response of thin gold films. J Nanosci Nanotech 2:427–433CrossRef

48.

Espinosa HD, Prorok BC, Fischer M (2003) A methodology for determining mechanical properties of freestanding thin films and MEMS materials. J Mech Phys Sol 51:47–67CrossRef

49.

Espinosa HD, Prorok BC, Peng B (2004) Plasticity size effects in free-standing submicron polycrystalline FCC films subjected to pure tension. J Mech Phys Sol 52:667–689CrossRef

50.

El Khakani MA, Chaker M, Jean A, Boily S, Kieffer JC, O’Hern ME, Ravet MF, Rousseaux F (1994) Hardness and Young’s Modulus of Amorphous a-SiC Thin Films Determined by Nanoindentation and Bulge Tests. J Mater Res 9:96–103CrossRef

51.

Pang X, Gao K, Yang H, Qiao L, Wang Y, Volinsky A (2007) Interfacial Microstructure of Chromium Oxide Coatings. Adv Eng Mater 9:594–599CrossRef

52.

Mizuno S, Verma A, Tran H, Lee P, Nguyen B (1996) Dielectric constant and stability of fluorine doped PECVD silicon oxide thin films. Thin Solid Films 283:30–36CrossRef

53.

Mober A (2008) Blast cleaning technology. Springer, BerlinCrossRef

54.

Shackelford JF, Alexander W (2001) CRC materials science and engineering handbook. CRC, Boca Ratan

55.

Hess P (1996) Laser diagnostics of mechanical and elastic properties of silicon and carbon films. Appl Surf Sci 106:429–437CrossRef

56.

Boch P, Glandus JC, Jarrige J, Lecompte JP, Mexmain J (1982) Sintering, oxidation and mechanical properties of hot pressed aluminum nitride. Ceram Int 8:34–40CrossRef

57.

Engdahl G (2000) Handbook of giant magnetostrictive materials. Academic, San Diego

58.

Liang C, Morshed S, Prorok BC (2007) Correction for Longitudinal Mode Vibration in Thin Slender Beams. Appl Phys Lett 90:221912CrossRef

59.

Ferrari AC (2004) Diamond-like carbon for magnetic storage disks. Surf Coat Tech 180:190–206CrossRef

Titel: A Discontinuous Elastic Interface Transfer Model of Thin Film Nanoindentation
verfasst von: B. Zhou
B. C. Prorok
Publikationsdatum: 01.07.2010
Verlag: Springer US
Erschienen in: Experimental Mechanics / Ausgabe 6/2010
Print ISSN: 0014-4851
Elektronische ISSN: 1741-2765
DOI: https://doi.org/10.1007/s11340-009-9309-7

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