Quantitative investigation of the influence of carbon surfactant on Ge surface diffusion and island nucleation on Si(100)

Vanacore, Giovanni Maria; Zani, Maurizio; Isella, Giovanni; Osmond, Johann; Bollani, Monica; Tagliaferri, Alberto

doi:10.1103/physrevb.82.125456

Cited by 9 publications

(12 citation statements)

References 63 publications

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“…(1) it demonstrate that the gross features of our experimental results can be described based on the kinetics of the diffusion alone, and (2) it allows to quantify the scaling dependence of the island density in the random diffusion area on the diffusion length, as discussed in the next paragraph. Figure 3(f) shows the linear scaling behavior exhibited by n 0 when plotted as a function of 1/Dτ (D is the diffusion coefficient and τ is the annealing time), where Dτ is derived by √ the diffusion length (L = 2 Dτ ) from the diffusion profiles measured at each annealing temperature [32]. This confirms quantitatively the diffusive origin of the decreasing gradient of the island density at higher temperatures.…”

Section: Density Evolution: Diffusion Limited Effectssupporting

confidence: 61%

Monitoring the kinetic evolution of self-assembled SiGe islands grown by Ge surface thermal diffusion from a local source

Vanacore

Zani

Bollani³

et al. 2014

Nanotechnology

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In this paper we experimentally study the growth of self-assembled SiGe islands formed on Si(001) by exploiting the thermally activated surface diffusion of Ge atoms from a local Ge source stripe in the temperature range 600-700 °C. This new growth strategy allows us to vary continuously the Ge coverage from 8 to 0 monolayers as the distance from the source increases, and thus enables the investigation of the island growth over a wide range of dynamical regimes at the same time, providing a unique birds eye view of the factors governing the growth process and the dominant mechanism for the mass collection by a critical nucleus. Our results give experimental evidence that the nucleation process evolves within a diffusion limited regime. At a given annealing temperature, we find that the nucleation density depends only on the kinetics of the Ge surface diffusion resulting in a universal scaling distribution depending only on the Ge coverage. An analytical model is able to reproduce quantitatively the trend of the island density. Following the nucleation, the growth process appears to be driven mainly by short-range interactions between an island and the atoms diffusing within its vicinities. The islands volume distribution is, in fact, well described in the whole range of parameters by the Mulheran's capture zone model. The complex growth mechanism leads to a strong intermixing of Si and Ge within the island volume. Our growth strategy allows us to directly investigate the correlation between the Si incorporation and the Ge coverage in the same experimental conditions: higher intermixing is found for lower Ge coverage. This confirms that, besides the Ge gathering from the surface, also the Si incorporation from the substrate is driven by the diffusion kinetics, thus imposing a strict constraint on the initial Ge coverage, its diffusion properties and the final island volume.

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Section: Density Evolution: Diffusion Limited Effectssupporting

confidence: 61%

Monitoring the kinetic evolution of self-assembled SiGe islands grown by Ge surface thermal diffusion from a local source

Vanacore

Zani

Bollani³

et al. 2014

Nanotechnology

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“…1(a)). SAM analysis 15 shows that the Ge content of the over-layer is approximately constant within the nucleation region (x < 20 lm) and its average value decreases from $0.8 at 600 C to $0.64 at 700 C. This temperature dependence reflects the thermally activated nature of the Si incorporation. When our results are compared to typical MBE data, where Ge concentration values of the wetting layer greater than 0.86 have been found even at 700 C, 26 it is evident that the thermal diffusion from a local source results in an enhanced intermixing within the OL, whose origin will be discussed in details later.…”

Section: Resultsmentioning

confidence: 94%

“…[15][16][17] Briefly, Ge stripes (width % 5 lm, thickness % 150 nm) are obtained by a lithographic patterning of pure Ge thin films, deposed by Low Energy Plasma Enhanced Chemical Vapour Deposition (LEPECVD), 24 and are annealed by Joule heating flowing a DC current through the Si(100) substrate. For the cases investigated here, the samples were annealed at 600 C for 15 min and at 700 C for 6 min.…”

Section: Experiments and Methodsmentioning

confidence: 99%

“…For this purpose, we have fabricated Ge stripes and annealed them in ultra-high vacuum (UHV) at different temperatures inducing Ge diffusion and islands self-assembly. As reported in previous works, [15][16][17] this methodology has provided a unique approach for the investigation of the factors governing the growth process. From our previous results, 17 we concluded that the island growth evolves in a diffusion-limited regime and it is mainly driven by the short-range interactions between the growing islands and the diffusing Ge atoms.…”

Section: Introductionmentioning

confidence: 97%

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Delayed plastic relaxation limit in SiGe islands grown by Ge diffusion from a local source

Vanacore

Nicotra

Zani

et al. 2015

Journal of Applied Physics

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The hetero-epitaxial strain relaxation in nano-scale systems plays a fundamental role in shaping their properties. Here, the elastic and plastic relaxation of self-assembled SiGe islands grown by surface-thermal-diffusion from a local Ge solid source on Si(100) are studied by atomic force and transmission electron microscopies, enabling the simultaneous investigation of the strain relaxation in different dynamical regimes. Islands grown by this technique remain dislocation-free and preserve a structural coherence with the substrate for a base width as large as 350 nm. The results indicate that a delay of the plastic relaxation is promoted by an enhanced Si-Ge intermixing, induced by the surface-thermal-diffusion, which takes place already in the SiGe overlayer before the formation of a critical nucleus. The local entropy of mixing dominates, leading the system toward a thermodynamic equilibrium, where non-dislocated, shallow islands with a low residual stress are energetically stable. These findings elucidate the role of the interface dynamics in modulating the lattice distortion at the nano-scale, and highlight the potential use of our growth strategy to create composition and strain-controlled nano-structures for new-generation devices

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“…It has been known that carbon is the dominant residual impurity on the surface of Ge substrates after chemical cleaning and preannealing in vacuum. 25) We use such residual carbon impurities to investigate the effect of carbon insertion, as shown schematically at the top left side of Fig. 1.…”

Section: Experimental Methodsmentioning

confidence: 99%

Suppression of segregation of the phosphorus δ-doping layer in germanium by incorporation of carbon

Yamada

Sawano

Uematsu

et al. 2016

Jpn. J. Appl. Phys.

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The successful formation of abrupt phosphorus (P) δ-doping profiles in germanium (Ge) is reported. When the P δ-doping layers were grown by molecular beam epitaxy (MBE) directly on Ge wafers whose surfaces had residual carbon impurities, more than a half the phosphorus atoms were confined successfully within a few nm of the initial doping position even after the growth of Ge capping layers on the top. On the other hand, the same P layers grown on Ge buffer layers that had much less carbon showed significantly broadened P concentration profiles. Current-voltage characteristics of Au/Ti/Ge capping/P δ-doping/n-Ge structures having the abrupt P δ-doping layers with carbon assistance showed excellent ohmic behaviors when P doses were higher than 1 ' 10 14 cm %2 and the capping layer thickness was as thin as 5 nm. Therefore, the insertion of carbon around the P doping layer is a useful way of realizing ultrashallow junctions in Ge.

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Quantitative investigation of the influence of carbon surfactant on Ge surface diffusion and island nucleation on Si(100)

Cited by 9 publications

References 63 publications

Monitoring the kinetic evolution of self-assembled SiGe islands grown by Ge surface thermal diffusion from a local source

Monitoring the kinetic evolution of self-assembled SiGe islands grown by Ge surface thermal diffusion from a local source

Delayed plastic relaxation limit in SiGe islands grown by Ge diffusion from a local source

Suppression of segregation of the phosphorus δ-doping layer in germanium by incorporation of carbon

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