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Metallic Island Coalescence: Molecular Dynamics Simulations of Boundary Formation and Tensile Strain in Polycrystalline Thin Films

Published online by Cambridge University Press:  15 February 2011

Andrew R. Takahashi
Affiliation:
MIT Department of Materials Science & Engineering, Cambridge, MA 02139-4307, U.S.A.
Carl V. Thompson
Affiliation:
MIT Department of Materials Science & Engineering, Cambridge, MA 02139-4307, U.S.A.
W. Craig Carter
Affiliation:
MIT Department of Materials Science & Engineering, Cambridge, MA 02139-4307, U.S.A.
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Abstract

Island coalescence during the early stages of polycrystalline film formation is thought to lead to the large values of tensile stress observed in experiments. Continuum models have been developed which are in semi-quantitative agreement with in-situ experimental observations of stress evolution during coalescence. However, the size of coalescing particles is in the nanometer range, so that atomistic treatments might be expected to more accurately reveal the mechanisms leading to coalescence stresses. We have performed molecular dynamics (MD) computational experiments in which small metallic clusters both in free space and on weakly bound substrates are allowed to coalesce. These atomistic simulations complement the finite element modeling (FEM) and analytical work on the tensile strains developed during grain boundary formation by coalescence. Additionally, the atomistic simulations implicitly capture the effects of anisotropy and special orientations. The MD simulations also provide atomic-level detail of the boundary structure that is absent in continuum models. We have focused on simulations of Ag as a high mobility material at and above room temperature and have begun studying Ni as a material that can behave either as a high or low mobility material depending on the deposition temperature(i.e. Ni has a higher activation energy for adatom motion than Ag.). We find that for small islands, the initial boundary formation occurs in times on the order of nanoseconds. For nanometer-sized clusters in free space and on traction-free substrates, the cluster can undergo large rotations prior to boundary formation. The simulated boundary heights fit well with both a FEM model and an analytical model. Work is ongoing to further quantify the results of the simulations and relate the atomistic forces and positions to the stress state. We are pursuing methods for including the effects of traction at the interface, both through continuum and discrete methods.

Type
Research Article
Copyright
Copyright © Materials Research Society 2003

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References

1. Hoffman, R.W.. Thin Solid Films, 34(2):185190, 1976.Google Scholar
2. Nix, W.D. and Clemens, B.M.. Journal of Materials Research, 14(8):34673473, 1999.Google Scholar
3. Freund, L.B. and Chason, E.. Journal of Applied Physics, 89(9):48664873, 2001.Google Scholar
4. Seel, S.C., Thompson, C.V., Hearne, S.J., and Floro, J.A.. Journal of Applied Physics, 88(12):70797088, 2000.Google Scholar
5. Rosato, V., Guillope, M., and Legrand, B.. Philosophical Magazine A, 59(2):321336, 1989.Google Scholar
6. Zhu, H.L. and Averback, R.S., Philosophical Magazine Letters, v. 73 n.1 p.27 (1996).Google Scholar