Local bending of thin film on viscous layer

被引：0

作者：

Zhang Y. ^{[1
]}

Liu Y. ^{[2
]}

机构：

[1] State Key Laboratory of Nonlinear Mechanics (LNM), Institute of Mechanics, Chinese Academy of Sciences

[2] Faculty of Information and Automation, Kunming University of Science and Technology

来源：

Acta Mechanica Solida Sinica | 2010年 / 23卷 / 2期

基金：

中国国家自然科学基金;

关键词：

Constraint; Deposition layer/dot; Local bending; Thin film; Viscous layer;

D O I：

10.1016/S0894-9166(10)60012-2

中图分类号：

学科分类号：

摘要：

Effects of deposition layer position and number/density on local bending of a thin film are systematically investigated. Because the deposition layer interacts with the thin film at the interface and there is an offset between the thin film neutral surface and the interface, the deposition layer generates not only axial stress but also bending moment. The bending moment induces an instant out-of-plane deflection of the thin film, which may or may not cause the so-called local bending. The deposition layer is modeled as a local stressor, whose location and density are demonstrated to be vital to the occurrence of local bending. The thin film rests on a viscous layer, which is governed by the Navier-Stokes equation and behaves like an elastic foundation to exert transverse forces on the thin film. The unknown feature of the axial constraint force makes the governing equation highly nonlinear even for the small deflection case. The constraint force and film transverse deflection are solved iteratively through the governing equation and the displacement constraint equation of immovable edges. This research shows that in some special cases, the deposition density increase does not necessarily reduce the local bending. By comparing the thin film deflections of different deposition numbers and positions, we also present the guideline of strengthening or suppressing the local bending.

引用

页码：106 / 114

页数：8

共 31 条

[1]

Medeiros-Ribeiro G., Bratkovski A.M., Kamins T.I., Ohlberg D.A.A., Williams R.S., Shape transition of germanium nanocrystals on a silicon (001) surface from pyramids to domes, Science, 279, 5349, pp. 353-355, (1998)

[2]

Floro J.A., Chason E., Sinclair M.B., Freund L.B., Lucadamo G.A., Dynamic self-organization of strained islands during SiGe epitaxial growth, Applied Physics Letters, 73, 7, pp. 951-953, (1998)

[3]

Ross F.M., Tersoff J., Tromp R.M., Coarsening of self-assembled Ge quantum dots on Si(001), Physical Review Letters, 80, 5, pp. 984-987, (1998)

[4]

Floro J.A., Chason E., Freund L.B., Twesten R.D., Hwang R.Q., Lucadamo G.A., Evolution of coherent islands in Si1-xGex/Si(001), Physical Review B, 59, pp. 1990-1998, (1999)

[5]

Kim H.J., Xie Y.H., Influence of the wetting-layer growth kinetics on the size and shape of Ge self-assembled quantum dots on Si(001), Applied Physics Letters, 79, 2, pp. 263-265, (2001)

[6]

Jin G., Liu J.L., Wang K.L., Temperature effect on the formation of uniform self-assembled Ge dots, Applied Physics Letters, 83, 14, pp. 2847-2849, (2003)

[7]

Lo Y.H., New approach to grow pseudomorphic structure over the critical thickness, Applied Physics Letters, 59, 18, pp. 2311-2313, (1991)

[8]

Yin H., Huang R., Hobart K.D., Suo Z., Kuan T.S., Inoki C.K., Shieh S.R., Duffy T.S., Kub F.J., Sturm J.C., Strain relaxation of SiGe islands on compliant oxide, Applied Physics Letters, 91, 12, pp. 9716-9722, (2002)

[9]

Barvosa-Carter W., Aziz M.J., Gray L.J., Kaplan T., Kinetically driven growth instability in stressed solids, Physical Review Letters, 81, 7, pp. 1445-1448, (1998)

[10]

Gerling M., Gustafsson A., Rich D.H., Ritter D., Gershoni D., Roughening transition and solid-state diffusion in short-period InP/In<sub>0.53</sub>Ga<sub>0.47</sub>As superlattices, Applied Physics Letters, 78, 10, pp. 1370-1372, (2001)

← 1 2 3 4 →