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The Effects of Hardness Variation on a CMP Model of Copper thin Films

Published online by Cambridge University Press:  31 January 2011

Joseph Bonivel ,
Yusuf Williams ,
Sarah Blitz ,
Micheal Kuo  and
Ashok Kumar
Joseph Bonivel
Affiliation:
jbonivel@mail.usf.edu, University of South Florida, College of Engineering, 4202 E. Fowler Avenue, Tampa, Florida, 33620, United States, 813-974-4101
Yusuf Williams
Affiliation:
ywilliam@mail.usf.edu, University of South Florida, Mechanical Engineering, Tampa, Florida, United States
Sarah Blitz
Affiliation:
sblitz@andrew.cmu.edu, Carnegie Mellon University, Mechanical Engineering, Pittsburgh, Pennsylvania, United States
Micheal Kuo
Affiliation:
mkuo@andrew.cmu.edu, Carnegie Mellon University, Mechanical Engineering, Pittsburgh, Pennsylvania, United States
Ashok Kumar
Affiliation:
akumar@mail.usf.edu, University of South Florida, Mechanical Engineering, Tampa, Florida, United States
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Abstract

With the rapid change of materials systems and decreased feature size, thin film microstructure and mechanical properties have become critical parameters for microelectronics reliability. An example of a major driver of this new technology is the data storage community who is pushing for 1 Terabit/square inch on its magnetic disk hard drives. This requires inherent knowledge of the mechanical properties of materials and in depth understanding of the tribological phenomena involved in the manufacturing process. Chemical mechanical polishing (CMP) is a semi-conductor manufacturing process used to remove or planarize ultra-thin metallic, dielectric, or barrier films (copper) on silicon wafers. The material removal rate (MRR), which ultimately effects the surface topography, corresponding to CMP is given by the standard Preston Equation, which contains the load applied, the velocity of the pad, the Preston coefficient which includes chemical dependencies, and the hardness of the material. Typically the hardness, a bulk material constant, is taken as a constant throughout the wafer and thereby included in the Preston coefficient. Through metallurgy studies, on the micro and nano scale, it has been proven that the hardness is dependent upon grain size and orientation. This research served to first relate the crystallographic orientation to a specific hardness value and secondly use the hardness variation in the previously developed particle augmented mixed-lubrication (PAML) model to simulate the surface topography and MRR during CMP. Recent test and results show that currently there is no empirical formula to relate the crystallographic orientation and thereby a critically resolved shear stress (CRSS) to a specific hardness value. The second part of this investigation utilized the variation in hardness values from the initial study and incorporated these results into the PAML numerical model that incorporates all the physics of chemical mechanical polishing (CMP). Incorporation of the variation of hardness resulted in a surface topography with a difference in roughness (Ra) from the bulk constant hardness value of 60 nm. The material removal rate (MRR) of the process differs by 2.17 μm3/s.

Keywords

CMPcrystallographic structurehardness
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 1157: Symposium E – Science and Technology of Chemical Mechanical Planarization (CMP) , 2009 , 1157-E08-06
Copyright
Copyright © Materials Research Society 2009

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References

1 Read, D.T., Dally, J.W., J. Mater. Res., 8(7), p. 15421549, 1993 Google Scholar
2 Weihs, T.P., Hong, S., Bravman, J.C., and Nix, W.D., J. Mater. Res. 3(5), p. 931942, 1988 Google Scholar
3 Baker, S.P. and Nix, W.D., J. Mater. Res. 9(12), p. 31313144, 1994 Google Scholar
4 Baker, S.P. and Nix, W.D., J. Mater. Res. 9(12), p. 31453152, 1994 Google Scholar
5 Doerner, M. and Nix, W., J. Mater. Res. 1, p. 601, 1986 Google Scholar
6 Terrell, E. J., and Higgs, C. F. III , J. of Tribology, vol. 131(1), p. 012201012210, 2009 Google Scholar
7 Terrell, E.J., Higgs, C.F. III , ASME Paper IJTC2007-44487, 2007 Google Scholar
8 Chen, J., Wang, W., Qian, L.H., and Lu, K., Scripta Materialia, v 49, n 7, p 645–50, 2003 Google Scholar
9 Barmak, K., Cabral, C. J. Vac. Sci. Technol. B, Vol. 24, No. 6, Nov/Dec p. 24852498, 2006 Google Scholar
10 Ignat, M., Scafidi, P., Duloisy, E., and Dijon, J., Materials Reliability in Microelectronics IV. Symposium, 135–46, 1994 Google Scholar
11 Fuji, T. and Akiniwa, Y., Key Engineering Materials, v 340-341, pt.2, 979–84, 2007 Google Scholar
12 Conrad, H., Narayan, J., Scripta Mater 42(11):1025–30, 2000 Google Scholar
13 Schiotz, J., Tolla, F.D. Di, Jacobsen, K.W., Nature 391 p.561, 1998 Google Scholar
14 Callister, W.D.. Fundamentals of Materials Science and Engineering, 2nd ed. Wiley & Sons.Google Scholar
15 Volinsky, A.A., Vella, J., Adhihetty, I.S., Sarihan, V., et.al, J. Mater. Res. 5(3) p. 16, 2001.Google Scholar
16 Suresh, S., Nieh, T.G., and Choi, B.W., Scripta Materialia, Vol. 41, No. 9, p. 951957, 1999 Google Scholar
17 Fang, T., and Chang, W., Microelectronic Engineering 65 p. 231238, 2003 Google Scholar
18 Nanz, G., Camilletti, L.E., IEEE Trans. Semicond. Manuf., 8(4), p. 382389, 1995 Google Scholar
19 Zantye, P.B., P. B. Sikder, A. A.K., Mater. Sci. Eng., R., 45(36), pp. 89220, 2004.Google Scholar
20 Castillo-Mejia, D., and Beaudoin, S., J. Electrochem. Soc., 150(2), pp. G96–G102. 2003 Google Scholar
21 Seok, J., Sukam, C.P., Kim, A.T., Tichy, J.A., and Cale, T.S., J. of Wear, 254(34), p 307320, 2003.Google Scholar
22 Dickrell, D.J., Dugger, M.T., Hamiltion, M.A., and Sawyer, W.G., J. Micromech Sys. 16(5), p. 12631268, 2007 Google Scholar
23 Beegan, D., Chowdhury, S., and Laugier, M.T., Surface Coatings Tech 201, p. 58045808, 2007 Google Scholar
24 Liu, Y., Ngan, A.H.W., Scripta Materialia Vol. 44, p.237241, 2001 Google Scholar
25 Shan, Z.W., Mishra, R.K., Syed, S.A., Warren, O.L., A. Minor, Nature Mater. 7 p.115, 2008 Google Scholar
26 Tseng, W., Liu, C., Dai, B., Yeh, C., Thin Solid Films Vol. 290-201, p. 458463, 1996 Google Scholar