Calorimetric evidence for structural relaxation in amorphous silicon

Roorda, S.; Doorn, Stephen K.; Sinke, W.C.; Scholte, P.M.L.O.; Loenen, Evert van

doi:10.1103/physrevlett.62.1880

Cited by 211 publications

(89 citation statements)

References 16 publications

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“…[22][23][24][25] Both the coordination defects and the bond angle distortion depend on the process history of a-Si, since it was widely shown that as-implanted a-Si, if annealed, undergoes a structural relaxation, with a heat release measured by differential scanning calorimetry at temperatures below the onset of crystallization. 26 In the mid nineties, after investigation through Raman spectroscopy, x-ray techniques, and photocarrier lifetime measurements, the origin of this relaxation was attributed to the recombination of the coordination defects, decreasing from $0.5% to 0.05%, and to the reduction of the bond angle distortion, from 12 to 9 . 20,27 Such a process was shown to be reversible, even if with an hysteresis loop, since ion implantation (leading to a damage level larger than $0.1 displacements per atom) performed on relaxed a-Si reproduces the same strain status as in the asimplanted a-Si.…”

Section: A Defects and Diffusion In Amorphous Simentioning

confidence: 99%

Mechanisms of boron diffusion in silicon and germanium

Mirabella

Salvador

Napolitani

et al. 2013

Journal of Applied Physics

103

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B migration in Si and Ge matrices raised a vast attention because of its inﬂuence on the production of conﬁned, highly p-doped regions, as required by the miniaturization trend. In this scenario, the diffusion of B atoms can take place under severe conditions, often concomitant, such as very large concentration gradients, non-equilibrium point defect density, amorphous-crystalline transition, extrinsic doping level, co-doping, B clusters formation and dissolution, ultra-short high-temperature annealing. In this paper, we review a large amount of experimental work and present our current understanding of the B diffusion mechanism, disentangling concomitant effects and describing the underlying physics. Whatever the matrix, B migration in amorphous (a-) or crystalline (c-) Si, or c-Ge is revealed to be an indirect process, activated by point defects of the hosting medium. In a-Si in the 450-650 C range, B diffusivity is 5 orders of magnitude higher than in c-Si, with a transient longer than the typical amorphous relaxation time. A quick B precipitation is also evidenced for concentrations larger than 2 x10^20 B/cm3. B migration in a-Si occurs with the creation of a metastable mobile B, jumping between adjacent sites, stimulated by dangling bonds of a-Si whose density is enhanced by B itself (larger B density causes higher B diffusivity). Similar activation energies for migration of B atoms (3.0 eV) and of dangling bonds (2.6 eV) have been extracted. In c-Si, B diffusion is largely affected by the Fermi level position, occurring through the interaction between the negatively charged substitutional B and a self-interstitial (I) in the neutral or doubly positively charged state, if under intrinsic or extrinsic (p-type doping) conditions, respectively. After charge exchanges, the migrating, uncharged BI pair is formed. Under high n-type doping conditions, B diffusion occurs also through the negatively charged BI pair, even if the migration is depressed by Coulomb pairing with n-type dopants. The interplay between B clustering and migration is also modeled, since B diffusion is greatly affected by precipitation. Small (below 1 nm) and relatively large (5-10 nm in size) BI clusters have been identiﬁed with different energy barriers for thermal dissolution (3.6 or 4.8 eV, respectively). In c-Ge, B motion is by far less evident than in c-Si, even if the migration mechanism is revealed to be similarly assisted by Is. If Is density is increased well above the equilibrium (as during ion irradiation), B diffusion occurs up to quite large extents and also at relatively low temperatures, disclosing the underlying mechanism. The lower B diffusivity and the larger activation barrier (4.65 eV, rather than 3.45 eV in c-Si) can be explained by the intrinsic shortage of Is in Ge and by their large formation energy. B diffusion can be strongly enhanced with a proper point defect engineering, as achieved with embedded GeO2 nanoclusters, causing at 650 °C a large Is supersaturation. These aspects of B diffusion are presented and discus...

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Section: A Defects and Diffusion In Amorphous Simentioning

confidence: 99%

Mechanisms of boron diffusion in silicon and germanium

Mirabella

Salvador

Napolitani

et al. 2013

Journal of Applied Physics

103

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“…23 Experiments have shown that during relaxation, the bond-angle dispersion and the density of point defects diminish. 5,8,12,24,25 This evolution has been simulated by molecular dynamics, too.…”

Section: Microscopic Interpretation Of the Energy Of Relaxation mentioning

confidence: 99%

“…An interesting prediction of our analysis is that the heat of crystallization of a-Si may be lower than the reported values of 11-14 kJ/mol. 23,38,39 If the density of defects were lower, Q cryst could be as low as 6.6 kJ/mol. In fact, the first crystallization experiments of a-Si reported a value of 9.2 kJ/mol.…”

Section: B Crystallizationmentioning

confidence: 99%

Quantification of the bond-angle dispersion by Raman spectroscopy and the strain energy of amorphous silicon

Roura¹,

Farjas²,

Cabarrocas³

2008

Journal of Applied Physics

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A thorough critical analysis of the theoretical relationships between the bond-angle dispersion in a-Si,⌬ , and the width of the transverse optical Raman peak, ⌫, is presented. It is shown that the discrepancies between them are drastically reduced when unified definitions for ⌬ and ⌫ are used. This reduced dispersion in the predicted values of ⌬ together with the broad agreement with the scarce direct determinations of ⌬ is then used to analyze the strain energy in partially relaxed pure a-Si. It is concluded that defect annihilation does not contribute appreciably to the reduction of the a-Si energy during structural relaxation. In contrast, it can account for half of the crystallization energy, which can be as low as 7 kJ/mol in defect-free a-Si.

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“…1(a), arises from the difference in Gibbs energy between hydrogenated amorphous Si (a-Si:H) and crystalline Si. 11 A unique feature of the in-plane growth lies in that the movement of catalyst drops can be guided by simple surface features, like a single edge step. This allows to determine the position and the growth path of the SiNWs 7,8,10,12 and offers an exciting opportunity to position the in-plane SiNWs during their growth without interrupting the vacuum.…”

mentioning

confidence: 99%

Growth-in-place deployment of in-plane silicon nanowires

Chen²,

O’Donnell³

et al. 2011

Applied Physics Letters

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International audienceUp-scaling silicon nanowire (SiNW)-based functionalities requires a reliable strategy to precisely position and integrate individual nanowires. We here propose an all-in-situ approach to fabricate self-positioned/aligned SiNW, via an in-plane solid-liquid-solid growth mode. Prototype field effect transistors, fabricated out of in-plane SiNWs using a simple bottom-gate configuration, demonstrate a hole mobility of 228 cm2/V s and on/off ratio >103. Further insight into the intrinsic doping and structural properties of these structures was obtained by laser-assisted 3 dimensional atom probe tomography and high resolution transmission electron microscopy characterizations. The results could provide a solid basis to deploy the SiNW functionalities in a cost-effective way

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Calorimetric evidence for structural relaxation in amorphous silicon

Abstract: Differential scanning calorimetry of amorphous silicon ( Show more

Cited by 211 publications

References 16 publications

Mechanisms of boron diffusion in silicon and germanium

Mechanisms of boron diffusion in silicon and germanium

Quantification of the bond-angle dispersion by Raman spectroscopy and the strain energy of amorphous silicon

Growth-in-place deployment of in-plane silicon nanowires

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