Figure 10 FE simulations (a) Total elastic energy of wires and d

Figure 10 FE simulations. (a) Total elastic energy of wires and dots as a function of the Si content. (b) Three-dimensional

maps of biaxial strain for pyramidal dots and wires for a Si content of 10%. (c) Average biaxial strain for wires and dots as a function of the Si content. (d) Total strain + surface energy for wires and dots as a function of volume. (e) Relative difference of the see more curves shown in (d). Wires and islands were modeled by realistic three-dimensional geometries (sketched in Figure  10b), for a Si composition ranging between 0 and 1. Both wires and islands have been assumed to be bounded by 113 facets and grown on a Ge(001) substrate. The aspect ratios of dots/wires were taken from STM measurements. Figure  10a shows the composition dependence of the total elastic energy density e relax for wires and islands. e relax is the residual strain energy stored AZD1480 research buy in a SiGe island(wire) and in the Ge substrate after relaxation and normalized to the island(wire) volume. As evident, the dots and the wires show almost the same elastic energy density for low Si contents, Momelotinib purchase whereas the elastic energy of the dots becomes lower for x ≳0.75. Indeed, Figure  10c shows that, at

high Si concentration, the strain relaxation is more efficient for the dots. The residual tensile strain obtained from FE calculations for a Si content x = 0.1, i.e., the composition determined by Raman spectroscopy, is found to be ε = +0.27%. To validate the model, it is interesting to compare this value with an experimental estimate of the strain. It is well-known the frequency position of the Si-Ge Raman mode depends on the residual biaxial strain as [27] (1) By

using the position of the SiGe alloy peak determined in our spectra, i.e., ω Si – Ge = 398.6 cm-1, we obtained a residual strain of +0.25%, a value which closely matches the result of the simulations. In order to discuss the relative stability of dots and Amino acid wires, the strain energy term has to be combined with the surface energy contribution to define the total-energy gain associated to the formation of a three-dimensional dot/wire of volume V, namely (2) where e WL is the strain energy density of a flat pseudomorphic Si0.1Ge0.9 film grown on Ge(001), γ S and γ B are, respectively, the surface energies of the lateral 113 facets and of the Ge(001) face of the substrate. C S  = SV -2/3 and C B  = BV -2/3 are shape-dependent factors which depend on the relative extension of the area of the lateral facets, S, and of the base area, B, of dots/wires. Previous results have shown that both the tensile strained Ge(113) [28] and the Ge(001) [29] surfaces have roughly the same surface energy value of about 65 meV/Å2; therefore, for the sake of simplicity, we assume γ S  = γ B  = 65 meV/Å2.

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