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Review

Optical and Structural Properties of Si Nanocrystals in SiO2 Films

Department of Chemistry, University of Helsinki, P.O. Box 55, FI-00014 Helsinki, Finland
*
Author to whom correspondence should be addressed.
Nanomaterials 2015, 5(2), 614-655; https://doi.org/10.3390/nano5020614
Submission received: 4 March 2015 / Revised: 7 April 2015 / Accepted: 10 April 2015 / Published: 22 April 2015
(This article belongs to the Special Issue Nanophotonic Materials)

Abstract

:
Optical and structural properties of Si nanocrystals (Si-nc) in silica films are described. For the SiOx (x < 2) films annealed above 1000 °C, the Raman signal of Si-nc and the absorption coefficient are proportional to the amount of elemental Si detected by X-ray photoelectron spectroscopy. A good agreement is found between the measured refractive index and the value estimated by using the effective-medium approximation. The extinction coefficient of elemental Si is found to be between the values of crystalline and amorphous Si. Thermal annealing increases the degree of Si crystallization; however, the crystallization and the Si–SiO2 phase separation are not complete after annealing at 1200 °C. The 1.5-eV PL quantum yield increases as the amount of elemental Si decreases; thus, this PL is probably not directly from Si-nc responsible for absorption and detected by Raman spectroscopy. Continuous-wave laser light can produce very high temperatures in the free-standing films, which changes their structural and optical properties. For relatively large laser spots, the center of the laser-annealed area is very transparent and consists of amorphous SiO2. Large Si-nc (up to ~300 nm in diameter) are observed in the ring around the central region. These Si-nc lead to high absorption and they are typically under compressive stress, which is connected with their formation from the liquid phase. By using strongly focused laser beams, the structural changes in the free-standing films can be made in submicron areas.

1. Introduction

Many limitations of modern electronic devices may be overcome by implementing photonics into electronics [1,2,3,4]. Integration of Si-based photonics with CMOS technology is a promising approach because it gives the possibility to merge electronics and photonics in the same chip [5,6,7,8,9]. Many optical functions such as, for example, light sources, amplifiers, waveguides, modulators, memory, and detectors should be achieved in order to fulfill this integration. Realization of a true monolithically fabricated injection Si laser with a small size is a particularly challenging task. The fundamental problem is the low light-emitting efficiency of bulk silicon due to its indirect band gap (~1.1 eV), which leads to long radiative times (~ms) and therefore, mostly non-radiative recombination of the excited carriers. The efficiency of the light emission can be enhanced by increasing the overlap of the wave functions of the electron and hole via, for example, spatial confinement [10,11,12,13]. The unusual properties of Si structures are observed when the size is less than the free exciton Bohr radius of 4.3 nm in bulk Si. This quantum confinement (QC) effect leads to the following main changes in the material properties: (i) an increase of the radiative probability due to delocalization of the wave functions in the momentum space, which increases the electron-hole wave function overlap and (ii) a shift in the emission wavelength to the visible region due to an increase of the band gap, which is controlled by the Si nanostructure size. Moreover, the number of sites within the volume of Si nanostructures, where non-radiative recombination can occur, decreases considerably. It should be mentioned that understanding electrical transport mechanisms in the systems considered below is very important for many applications [14]; however, this topic is outside the scope of the present review.
Porous Si is the first example of a Si-based material with enhanced luminescence efficiency. Strong room-temperature photoluminescence (PL) in visible spectral region from this material was discovered by Leigh Canham in 1990 [15]. Visible luminescence ranging from green to red in color was soon reported by Canham et al. [16] for other porous-Si samples and by other researchers [17,18] and ascribed to the quantum effects in Si structures with a size of ~3 nm. The blue shift of the PL and optical absorption with the increasing porosity (decreasing Si nanocluster sizes) provided the first important evidence that the QC plays an important role in light emission from porous Si. This blue shift is a result of the band gap expansion controlled by the size of Si nanostructures [13,19].
It was soon understood that oxidation of small Si crystallites has a great influence on the light emission [20,21]. The study by Wolkin et al. of oxidized porous Si has shown that the light-emitting centers can involve the Si=O covalent bonds located on the crystallite surface [22]. For oxygen-passivated Si crystallites, a stabilized electronic surface state is formed on a Si=O covalent bond and various recombination mechanisms can operate depending on the crystallite size. For larger sizes (>3 nm), recombination occurs via free excitons since the band gap is not wide enough to stabilize the Si=O surface state. For intermediate sizes (~2.5 nm), recombination involves a trapped electron localized on the Si atom of the Si=O bond and a free hole. For smaller sizes (<2 nm), recombination occurs via trapped excitons.
However, QC has been demonstrated for a number of Si nanomaterials. In contrast with oxygen passivation, for hydrogen-passivated porous Si, recombination occurs via free exciton states for all crystallite sizes and follows the expected QC behavior [22]. Ledoux et al. studied Si nanocrystals (Si-nc) prepared by pulsed CO2 laser pyrolysis of silane in a gas flow reactor and deposited on a substrate [23]. It was observed that the PL band was blue-shifted as the size of Si-nc decreased from 8 to 2.5 nm. This dependence clearly follows the QC model. The QC mechanism operates also for alkane-terminated Si-nc. Hannah et al. [24] convincingly demonstrated using pressure-dependent PL studies that the PL arises from the core-states of Si-nc with indirect-gap transitions. The same PL mechanism has also been reported to operate for Si-nc in silicon-nitride films [25,26].
Another attractive Si-based material, which is the focus of the present article, is composed of Si-nc embedded in a SiO2 matrix. This material is chemically and mechanically more stable compared to porous Si and also emits light in the visible region. Si-nc in silica films can be prepared by various methods such as, for example, molecular beam deposition (MBD) [27,28], Si-ion implantation [29,30,31,32], sputtering [33,34,35,36,37,38,39], plasma enhanced chemical vapor deposition (PECVD) [33,34,40,41,42], low pressure chemical vapor deposition with subsequent thermal oxidation [43,44,45], reactive evaporation of SiO powder in oxygen atmosphere [46], and electron beam deposition [47]. Two types of architectures are most commonly prepared: (i) Si-rich silicon oxide SiOx (x < 2) films [31,33,40,48,49] and (ii) SiOx/SiO2 [37,46,47,50,51,52,53] and Si/SiO2 [27,28,35,54,55,56,57] superlattices (SLs). Si-nc are formed in these materials by furnace annealing above 1000 °C. Studies of Si-nc in SiO2 have been particularly stimulated by the observation of optical gain in this material [58,59]. In addition to PL, electroluminescence in visible region from porous Si and from Si-nc in SiO2 has been reported [60,61].
The origin of light emission from Si-nc in a SiO2 matrix is still controversial. It seems that the conclusions on the mechanism of the light emission from oxidized porous Si [20,21,22,62] are relevant to Si-nc in SiO2. Similarly, the PL of Si-nc (sizes > 3 nm) in SiO2 can be ascribed to the QC effect [63,64,65,66]. On the other hand, the importance of the Si-nc/SiO2 interface in the light-emitting properties has been stressed [31,35,67,68] and, in particular, the defect origin of the PL has been discussed [27,29,31,69,70,71]. Godefroo et al. have convincingly demonstrated that defects are the dominant source of the 1.5-eV PL [52]. In their experiment, an amorphous SiO/SiO2 SL grown by reactive evaporation of SiO powders in an oxygen atmosphere was thermally annealed at 1100 °C for 1 h under N2 atmosphere to produce Si-nc. The authors could switch the PL mechanism between the QC and defect mechanisms by passivation with hydrogen and ultraviolet illumination, respectively.
Optoelectronic applications of Si-based materials require knowledge of their optical and structural properties. For SiOx (x < 2) films prepared by PECVD, the energy-filtered transmission electron microscopy (EFTEM) show that the Si–SiO2 phase separation starts after annealing at 900 °C for 1 h under N2 atmosphere when Si clusters become visible in an oxide matrix [72]. The dark-field (DF) transmission electron microscopy (TEM) technique reliably shows that the Si clusters are amorphous for annealing temperatures of 900–1000 °C, and their crystallization begins at 1100 °C. Higher annealing temperatures promote further crystallization of the Si clusters. The Si-nc size as a function of the annealing temperature and Si content has been studied for samples prepared by different deposition methods. For samples prepared by PECVD, the TEM results indicate that the Si-nc sizes increase with the increasing annealing temperature for a given Si content and with the Si content for a given annealing temperature [40]. The increase of the Si-nc sizes with the annealing temperature is also observed for SiOx films grown by magnetron sputtering [37]. For SiOx films prepared by ion implantation, the nucleation and pure growth stages of the nanocrystal population are almost over after 1 min of annealing at 1100 °C in N2 [31]. For longer annealing periods, the sizes of Si-nc increase due to coalescence or Ostwald ripening process [31,73].
Several methods have been employed to study optical constants of different materials containing Si-nc. These methods include, for example, optical ellipsometry [74,75,76] and m-line measurements [77,78,79]. The analysis of the optical properties often uses the Bruggeman effective-medium approximation [80,81,82]. The Tauc-Lorentz model provides optical constants of Si-nc deposited on a substrate [82]. The results show that the optical properties of Si-nc are quite different from those of amorphous and crystalline Si. It has been found that at a given wavelength, the refractive index of SiOx films increases for larger Si-nc for Si-ion implanted samples [74] and for larger Si content for PCVD samples [75]. Chen et al. have developed a quantitative approach of obtaining depth profiles of the optical constants [81]. Moreno et al. report that the refractive index of Si-nc is lower than that of amorphous and crystalline bulk Si [80]. They also conclude that the refractive index is rather independent of the Si clusters sizes (3.6–4.6 nm) and is mostly affected by the degree of crystallinity. For SiOx/SiO2 SLs prepared by magnetron sputtering, negative optical birefringence (~1%) was observed, originating from the periodical set of parallel planes of two different materials constituting the SL [77,78]. At a given wavelength, the absorption coefficient of annealed SiOx films prepared by magnetron sputtering and PECVD increases with the Si content [33,76,83]. The increase of the Si-nc mean diameter leads to an increase of absorption in porous Si [84] and in SiOx films prepared by ion implantation [80]. For a fixed Si content, the absorption coefficient of films prepared by magnetron sputtering and PECVD decreases with the increasing annealing temperature, which is due the amorphous-to-crystalline transition of Si in the samples [33].
Another method of measuring the optical properties of SiOx films is based on the PL-filtering effect. A silicon oxide layer containing Si-nc on a silica substrate forms a planar waveguide. Spectral filtering of the PL occurs when the PL is detected from the waveguide edge along the film surface. This effect has been found for Si/SiO2 SLs [57] and for SiOx films (x < 2) on silica substrate [79,85,86,87]. The detailed description of this effect is presented later.
The Tauc relation [88] allows one to estimate the band gap of SiOx films containing Si-nc [31,33,36,44,74,89,90]. A study of Si-nc deposited on a silica substrate shows that the electronic band structure of Si-nc is quite different from that of bulk silicon and that the band gap increases as the Si-nc size decreases [82]. The latter observation is explained by the QC effect. The increase of the band gap for smaller Si-nc is also observed for implanted SiOx samples [31,74]. The absorption threshold is blue-shifted for smaller Si-nc, which indicates the QC effect on the Si-nc band gap [33,36,84,90,91].
Laser annealing is an interesting approach to change the structural and optical properties of Si-based materials. The heating effect of pulsed radiation is especially strong [92]. However, it can also be substantial for continuous-wave (CW) irradiation of free-standing porous Si films [93]. A similar heating effect of CW laser radiation is observed in free-standing SiOx films leading to a strong increase of the Raman signal of Si-nc [56,94,95,96]. Si-nc prepared by laser annealing show high compressive stress (~3 GPa), which is evidenced by an up-shift of the Raman band [56,96]. The compressive stress is formed in a solid SiO2 matrix when the volume of Si-nc suddenly increases after its crystallization from the liquid phase. The high stress can be relaxed by irradiating the stressed Si-nc with lower laser power [56]. Free-standing films are used to obtain the above described laser-induced effects because for films on substrates the laser-induced heat is reduced due to thermal flux to substrate [97]; however, it is still observable [98].
In agreement with the experimental observations, the theoretical simulations of isolated hydrogen-passivated Si nanostructures show that the band gap and the PL peak position change according to QC [13,19]. The behavior of these parameters is different for oxidized Si-nc [99]. Theoretical studies highlight the importance of the interface region between Si-nc and a SiO2 matrix for the light-emitting properties [100,101]. The absorption edge tends to be red-shifted due to the formation of the Si=O or Si–O–Si bonds at the Si/SiO2 interface [102,103,104]. The presence of oxygen atoms bonded to the surface of Si-nc as well as deformation of Si-nc are found to influence the optical band gap [105]. Luppi et al. have considered small Si-nc (up to 1 nm in diameter) by applying ab initio calculations [106]. In the case of the Si–O–Si bridge bond at the cluster surface, an emission peak at about 1.5 eV is obtained. In accord, the PL in this region is often observed experimentally from silica films containing Si-nc. The calculated emission peak is red-shifted with respect to the absorption, which is also in agreement with the experimentally observed Stokes shifts between the absorption and PL spectra.
Theoretical calculations show that the surrounding matrix can produce some strain on Si-nc [107,108,109], and this strain depends on the oxidation degree [110,111]. The magnitude of strain affects the band gap, which shows an oscillating behavior with the Si-nc size, not strictly following the QC rule [110]. Moreover, the disorder of nanoclusters has a large effect on their optoelectronic properties [112,113]. In particular, amorphization reduces the optical band gap and increases the absorption strength in the visible range.
Guerra and Ossicini have calculated the recombination rates for different classes of Si-nc in the diameter range of 0.2–1.5 nm [114]. The authors also consider different conditions of passivation, strain, and symmetry in order to find the best conditions of radiative emission. As a result, they have found that the smallest, highly oxidized, crystalline clusters are the most optically active Si/SiO2 structures.

2. Results and Discussion

2.1. Furnace-Annealed Films

In this section, we describe the properties of SiOx (x < 2) films on silica substrates for different annealing temperatures (400–1200 °C) and Si contents (x from ~1.3 to ~1.98) [115,116,117,118]. The SiOx films (thickness from ~1.5 to ~2.5 μm) are deposited on silica substrates by MBD. The MBD samples are compared with samples prepared by ion implantation [118].

2.1.1. Correlation between Optical and Structural Properties

The as-prepared MBD films (annealed at 400 °C for better mechanical stability) with substantial Si content show a broad Raman band at ~470 cm–1, which is characteristic of amorphous Si (Figure 1) [27,48,55,119,120]. After annealing above 1000 °C, crystallization of the amorphous Si inclusions occurs as evidenced by the narrowing and upshift of the Raman band to ~518 cm–1 (Figure 1). When measured with low laser intensity, the Raman band position (518–519 cm–1) is rather independent of the Si content and of the annealing temperature in the 1100–1200 °C range. According to the phonon confinement model [121,122], this result suggests that the Si-nc sizes evidenced by Raman spectroscopy do not change much under these conditions. However, growth of Si-nc with increasing annealing temperature was observed for SiOx films prepared by other deposition methods [37,40].
For MBD SiOx films with very small excess of Si (x > 1.9), the Raman bands of amorphous and crystalline Si are nearly invisible [116], in qualitative agreement with the earlier results [27]. The reason for this observation is the small amount of properly coordinated Si atoms (Si atoms bonded to four “bulk” Si atoms) for samples with low Si contents. A similar explanation was applied in a study of amorphous Si/SiO2 SLs, where the Raman bands of amorphous Si were observed for thicker Si layers (≥2 nm) and the Raman-scattering cross section decreased for thinner Si layers [55,123].
As the annealing temperature increases, the low-frequency shoulder in the Raman spectra responsible for disordered Si and/or small Si clusters gradually decreases (Figure 1). However, even after annealing at 1200 °C, the low-frequency component of the Raman band does not disappear and its area is comparable to that of the high-frequency component. As a possibility, small Si grains in a SiO2 matrix may be disordered even after annealing at this temperature whereas larger Si grains are crystallized.
X-ray photoelectron spectroscopy (XPS) confirms that the structural reorganization is not complete after furnace annealing (Figure 2). The Si–SiO2 phase separation increases with the annealing temperature, which is evidenced by the increasing amount of elemental Si and SiO2 and the decreasing amount of SiO. However, a large proportion of suboxides (10–15 at. % for x = 1.7) is still detected after annealing at 1200 °C [116]. This result indicates incomplete Si–SiO2 phase separation in these materials.
Figure 1. Raman spectra of a SiO1.75 film as-prepared and annealed at 1000 and 1200 °C (fitted by two Gaussians). The spectra are vertically shifted for better presentation. The Raman spectra are measured with laser intensity of ~103 W cm–2 at the sample. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
Figure 1. Raman spectra of a SiO1.75 film as-prepared and annealed at 1000 and 1200 °C (fitted by two Gaussians). The spectra are vertically shifted for better presentation. The Raman spectra are measured with laser intensity of ~103 W cm–2 at the sample. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
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Figure 2. Composition of a SiO1.7 film provided by X-ray photoelectron spectroscopy (XPS) as a function of the annealing temperature. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
Figure 2. Composition of a SiO1.7 film provided by X-ray photoelectron spectroscopy (XPS) as a function of the annealing temperature. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
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Figure 3. Band gap of SiOx films annealed at 1100 °C as a function of x. The inset shows the band gap of a SiO1.4 film as a function of the annealing temperature. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
Figure 3. Band gap of SiOx films annealed at 1100 °C as a function of x. The inset shows the band gap of a SiO1.4 film as a function of the annealing temperature. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
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Additional information about the properties of SiOx films can be obtained from the band gap. For a given annealing temperature (from 900 to 1200 °C), the band gap of SiOx films increases as the Si content decreases [116]. For annealed at 1100 °C, the band gap increases from 2.2 to 2.6 eV as x increases from 1.3 to 1.8 (Figure 3), meaning that the Si-nc sizes somewhat decrease. According to the ab initio calculations for Si-nc with oxygen bonds at the Si/SiO2 interface, the obtained band gap change (2.2–2.6 eV) corresponds only to a marginal change of the Si-nc sizes, the average size being ~1 nm [124]. On the other hand, the position of the maximum of the Raman bands at 518–519 cm–1 corresponds to larger sizes (3–4 nm) [121,122], and this value is supported by TEM measurements of similar materials [125]. These different estimates can be connected with low sensitivity of the Raman and TEM methods to very small Si grains. The low-frequency Raman scattering at 490–500 cm–1 can be contributed by smaller Si-nc (1–2 nm) that may be partially disordered, which would agree with the Si-nc sizes derived from the band gaps. It should also be mentioned that the band gap of Si clusters is a complex function of a number of parameters in addition to the size, such as the crystallinity, strain due to the SiO2 matrix, and degree of oxidation [110,112]. Moreover, the Tauc law is generally applicable for amorphous semiconductors with absorption coefficients >104 cm–1 [88]. Thus, the band gaps obtained by applying the Tauc law to crystalline Si grains with lower absorption may be somewhat inaccurate.
The band gap of SiOx (x ~ 1.4 [116] and x ~ 1.8 [118]) films increases with the annealing temperature (see the inset in Figure 3). This increase can be explained by amorphous-to-crystalline transitions of Si clusters rather than by a decrease of their sizes, following the discussions by Mirabella et al. [33]. Indeed, the Si-nc sizes should rather increase with the annealing temperature [40,42] even though this increase for the MBD samples seems to be minor as suggested by the Raman spectra.
By varying the Si content and annealing temperature, one can control the refractive index and the absorption coefficient of SiOx films. For a given annealing temperature, the refractive index increases with the Si content (Figure 4a) [118] as also reported previously [49,79]. Extrapolation of the data to x = 2 yields the refractive index of silica (1.456), which is a good verification of our results. The obtained values are also in agreement with other experimental results for annealing at 1100 °C, λ = 632 nm, and x ~ 1.38–1.63 [80]. For a given x, the refractive index typically decreases upon annealing at temperatures from 1000 to 1100 °C but increases in the 1100–1200 °C annealing temperature range [116].
The measured refractive index is interesting to compare with the values derived from the effective medium approximation and the chemical compositions measured by XPS (Figure 4a for 1100 °C and in Table 1 for x ~ 1.75). The agreement between the theory and the experiment is good. The observed small discrepancy can be due to the limitations of the used model (see Section 3.3). It is also possible that the refractive index of nanostructures is different from that of the bulk materials. Finally, in the XPS analysis, the mixture of different suboxides constitutes the SiO component, and this can also contribute to the error.
Figure 4. (a) TE refractive index and (b) birefringence of SiOx films annealed at 1000 °C (triangles), 1100 °C (squares), 1150 °C (diamonds), and 1200 °C (circles) as a function of x. The open squares show the refractive index obtained using the effective medium approximation and the XPS results for annealing at 1100 °C. The dashed line is a guide for the eye. (a) is reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
Figure 4. (a) TE refractive index and (b) birefringence of SiOx films annealed at 1000 °C (triangles), 1100 °C (squares), 1150 °C (diamonds), and 1200 °C (circles) as a function of x. The open squares show the refractive index obtained using the effective medium approximation and the XPS results for annealing at 1100 °C. The dashed line is a guide for the eye. (a) is reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
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Table 1. Experimental refractive index nexp and absorption coefficient αexp of a SiO1.75 film for different annealing temperatures Tann and the estimates for the refractive index nest and extinction coefficient kest from the effective medium approximation. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
Table 1. Experimental refractive index nexp and absorption coefficient αexp of a SiO1.75 film for different annealing temperatures Tann and the estimates for the refractive index nest and extinction coefficient kest from the effective medium approximation. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
Tann (°C)nexpαexp (104 cm1)nestkest(SiO)kest(Si)
400-1.571.5750.451.25
900-0.561.570.071.25
10001.64 *0.134 *1.56 *00.77
11001.610.1261.5600.53
11501.640.1201.56500.535
12001.670.1281.5700.48
* Obtained by extrapolation of the data to x = 1.75.
The SiOx film material prepared by MBD is found to be birefringent [79]. The classical theory of an isotropic asymmetrical planar waveguide predicts that the cut-off positions for the TE modes (with polarization parallel to the film) are at longer wavelengths than the TM cut-off positions (with polarization perpendicular to the film) [126,127]. However, the opposite order between the TE and TM peaks is found for some samples (see Figure 20a in Section 3.3). This reversed order of the TE and TM peaks is explained assuming positive optical birefringence, which is connected with the non-spherical shape of Si-nc [79]. Non spherical Si-nc have been observed in similar materials using the combination of electron tomography with plasmon-filtered microscopy [128]. It appears that that the optical birefringence is higher for SiOx films with the higher Si content and for lower annealing temperature (Figure 4b) [79,116]. Similar values of birefringence are obtained by m-line measurements [115].
The absorption coefficient of SiOx films can be analyzed using the effective medium approximation and the XPS data (Table 1). For an as-prepared SiO1.75 film, the extracted extinction coefficient of the SiO phase (0.45) is much larger than the value known for bulk SiO (0.055) if the extinction coefficient of amorphous Si (k = 1.25) is used for elemental Si. This mismatch would be smaller if the amount of elemental Si was underestimated by XPS and/or the extinction coefficient of nanoscale amorphous Si was larger than that of bulk amorphous Si. For annealing at 900 °C, our estimates agree with the extinction coefficients of bulk SiO and amorphous Si. For films annealed above 1000 °C, the SiO component is found to be very transparent, in contrast to bulk SiO, and this difference is possibly connected with ultra-small sizes of the suboxide regions.
As the annealing temperature increases, the estimated extinction coefficient of elemental Si decreases (Table 1), which is interpreted in terms of gradual crystallization of Si [115,116]. However, this process in not complete even after annealing at 1200 °C, because the calculated extinction coefficient (0.48 for x = 1.75) is much larger than that of crystalline Si (0.079); thus, Si is partially disordered, in agreement with the earlier results [42]. This “disordered” Si should differ from “ordinary” amorphous Si because no Raman band at 470 cm–1 is present for the films annealed above 1000 °C. Instead, the disordered Si grains may contribute to the Raman scattering at 490–500 cm–1, which is observed in Raman spectra of SiOx films annealed up to 1200 °C (Figure 1). As a possibility, ultra-small Si grains in a SiO2 matrix may be disordered even after the annealing whereas larger Si grains are crystallized. The presence of this disordered Si may explain the surprisingly large absorption of the annealed SiOx films. Moreover, the optical properties of bulk and nanoscale Si may differ, and the absorption by SiO inclusions cannot be completely excluded. This explanation of the relatively large absorption coefficient of annealed SiOx films is quite speculative, and additional experimental data are required to draw more accurate conclusions.
The absorption coefficient and the integrated Raman intensity of Si-nc are nearly proportional to the amount of elemental Si obtained by XPS (see Figure 5 for absorption) [115,116], in agreement with the earlier results [48]. It follows that elemental Si determines the absorption coefficient and the Si-nc Raman signal. A similar conclusion is made for SiOx films deposited by magnetron sputtering [129]. On the other hand, we have obtained that the Raman scattering cross-section of elemental Si in SiOx films prepared by MBD is about three times smaller compared to that of crystalline Si [116]. This difference can be explained by several factors. Ultra-small Si-nc (diameters < 2 nm) may be invisible by Raman spectroscopy due to the low proportion of “properly” coordinated Si atoms. The interaction with a SiO2 matrix can change the coordination of Si-nc, and this effect is stronger for smaller Si particles. In principle, the broad band gap of Si-nc may affect the Raman cross-section due to the resonance effect. Finally, the complex character of interaction of light with Si-nc embedded in SiO2 is not well understood. The present results are not enough to give a more reliable interpretation of these observations.
Figure 5. Absorption coefficient at 488 nm for annealing at 1000 °C (triangles), 1100 °C (squares), 1150 °C (diamonds), and 1200 °C (circles) as a function of the amount of elemental Si. The dashed line is a guide for the eye. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
Figure 5. Absorption coefficient at 488 nm for annealing at 1000 °C (triangles), 1100 °C (squares), 1150 °C (diamonds), and 1200 °C (circles) as a function of the amount of elemental Si. The dashed line is a guide for the eye. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
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2.1.2. Photoluminescence of the MBD Samples

For SiOx films annealed up to 900 °C, weak PL with the maximum at 650–750 nm is observed (Figure 6a). This light emission is usually assigned to different thermodynamically unstable radiative defects, for instance, nonbridging oxygen-hole centers or E´-type defects [31,32,130,131,132]. After annealing above 900 °C, the PL maximum shifts towards longer wavelengths (~800 nm) and the PL intensity strongly increases [116,118], which agrees with numerous literature reports [27,34,42,53,72,91]. The highest PL intensity is observed for x ≅ 1.8–1.9 and annealing at 1100–1150 °C [116]. Annealing at 1200 °C decreases the PL intensity. A similar decrease of the PL intensity was also observed for SiOx (1.05 < x < 1.75) films prepared by magnetron sputtering [34]. A slightly different behavior is observed for SiOx (1.05 < x < 1.75) films prepared by PECVD. For these samples, the PL intensity increases with the annealing temperature up to 1250 °C [34,40].
Figure 6. Photoluminescence (PL) spectra of (a) a SiO1.4 film annealed at different temperatures and (b) SiOx films with different x annealed at 1100 °C. The SiOx films are prepared by molecular beam deposition (MBD). The hole in the spectra around 970 nm is due to the second order of the notch filter. Notice the multiplication factor in (a). (b) is reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
Figure 6. Photoluminescence (PL) spectra of (a) a SiO1.4 film annealed at different temperatures and (b) SiOx films with different x annealed at 1100 °C. The SiOx films are prepared by molecular beam deposition (MBD). The hole in the spectra around 970 nm is due to the second order of the notch filter. Notice the multiplication factor in (a). (b) is reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
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The enhancement of the 1.5-eV PL by annealing at ≥1000 °C is accompanied by the formation of Si-nc detectable by Raman spectroscopy [40,48,49,116,118]. This correlation seemingly suggests that the PL directly originates from these Si-nc. On the other hand, the PL intensity is the highest for samples with relatively small Si contents [48,49]. Moreover, for x > 1.9, no Si-nc and elemental Si are evidenced by the Raman and XPS measurements, respectively, whereas the PL is strong (Figure 6b). In fact, the PL quantum yield steadily increases as the absorption coefficient and the Si content decrease (Figure 7) [116,117]. These observations suggest that the Si-nc observed in the Raman spectra and detected by XPS as elemental Si are not direct light-emitting centers, which is in agreement with the defect origin of the 1.5-eV PL [52].
The PL position of our SiOx films is rather stable for different annealing temperatures (above 1000 °C) and Si contents (see Figure 6). These results seem to disagree with the studies of oxidized Si-nc prepared by magnetron sputtering [63]. Those experiments show that the PL position is size dependent for relatively large sizes (>3 nm) that are reliably measured by TEM. However, Wolkin et al. have shown that oxidation of Si-nc stabilizes the PL position for smaller Si-nc (<3 nm) [22].Thus, the stability of the PL position in our samples is consistent with the hypothesis that the observed PL originates from very small Si grains (<3 nm). In general, one has to distinguish different types of Si-nc samples. For example, the experiments on hydrogen-passivated Si-nc show that the PL of Si-nc with diameters smaller than 3 nm should be below 600 nm [23], which is not the case for our samples. This difference in PL positions can be explained by the decrease of the bandgap upon passivation of Si-nc with oxygen [110,133].
Figure 7. Relative PL quantum yield for SiOx films prepared by MBD for annealing at 1000 °C (triangles), 1100 °C (squares), 1150 °C (diamonds), and 1200 °C (circles) as a function of the absorption coefficient at 488 nm. The inset shows the relative PL quantum yield as a function of the amount of elemental Si for annealing at 1100 °C. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
Figure 7. Relative PL quantum yield for SiOx films prepared by MBD for annealing at 1000 °C (triangles), 1100 °C (squares), 1150 °C (diamonds), and 1200 °C (circles) as a function of the absorption coefficient at 488 nm. The inset shows the relative PL quantum yield as a function of the amount of elemental Si for annealing at 1100 °C. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
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Now we discuss the possibility of assigning the 1.5-eV PL to defects and/or ultra-small Si grains. By analogy with oxidized porous Si [22,62], the light-emitting centers can be related to the Si=O covalent bonds [27,48] or to the bridge Si–O–Si bonds suggested by theory [106]. Ultra-small (below ~1 nm) oxidized Si grains considered by theory [114] is another candidate to explain the red PL. Several observations are consistent with the latter interpretation. First, the stable PL position for different Si content suggests small sizes of the light-emitting clusters (<3 nm) [22]. The calculated band gaps of Si clusters with diameters ~1 nm are 2–3 eV [115], which agrees with the band gaps obtained for our samples (Figure 3) [116]. The short PL lifetimes obtained for our samples (~1 μs) [117] also suggest that the PL originates from Si-nc that are quite smaller than 3 nm, for which the PL lifetime is ~40 μs [116,134]. Moreover, the theoretical study by Luppi et al. suggests that Si-nc with diameters up to 1 nm and with a Si–O–Si bridge bond at the surface emit light at ~1.5 eV [106], which is observed for our samples. The decrease of the PL intensity after annealing at 1200 °C is reasonable if the amount of small optically active Si-nc decreases at this temperature.
The direct excitation of the light-emitting centers by laser light is possible. As another excitation mechanism, laser light may be absorbed by relatively large Si clusters, and then the excitation is transferred to the light-emitting centers located at the Si-nc/SiO2 interface [68,135] or in more disordered areas [48,117]. Non-radiative defects such as dangling bonds at the Si‑nc/SiO2 interface as well as defects inside and outside the Si-nc can efficiently trap the excitation and therefore quench the PL [53]. Annealing at ~1100 °C presumably decreases the amount of these non-radiative defects and/or intensifies the energy transfer to the radiative centers, which enhances the PL. It has been shown that a considerable amount of non-paramagnetic near- and sub-gap defect states still remains after annealing, which drastically limits the PL quantum yield [136]. The amount of the light-emitting centers may increase upon annealing; however, no direct evidence of this is available.
Kusova et al. have suggested that compressive stress on Si-nc in a SiO2 matrix can redshift the PL [137]. However, it is difficult to estimate stress of very small Si-nc using Raman spectroscopy, due to their low Raman scattering cross-section. Such small Si-nc can contribute to the broad low-frequency shoulder at ~500 cm–1 (Figure 1). On the other hand, the Raman bands at 518–519 cm–1 observed in our samples feature unstressed Si-nc with sizes of ~4 nm [121] that are also detected by TEM [125]. It can be speculated that no substantial stress is exerted also on smaller Si-nc.

2.1.3. Comparison of the Implanted and MBD SiOx Samples (x ~ 1.8)

After preparation, the structural and optical properties of the MBD and implanted samples are very different [118]. Amorphous Si clusters (>2 nm) are present in the as-grown MBD film, as indicated by a broad Raman band at ~470 cm–1 (Figure 1) and by a large absorption coefficient (Figure 8a). For the implanted samples annealed below 900 °C, the absence of Raman bands of Si and very low absorption (Figure 8a) suggest that only very small Si clusters (presumably with sizes up to ~1 nm) may be present in the material [55,123].
Figure 8. (a) Absorption coefficient at 488 nm for the MBD (squares) and implanted (circles) samples and (b) Normalized intensity (solid symbols) and position of the maximum (open symbols) of the Raman bands as a function of the annealing temperature. The Raman intensity is normalized by the effective film thickness (see Section 3.2). Reproduced with permission from [118]. Copyright Wiley-VCH Verlag GmbH & Co. KGaA.
Figure 8. (a) Absorption coefficient at 488 nm for the MBD (squares) and implanted (circles) samples and (b) Normalized intensity (solid symbols) and position of the maximum (open symbols) of the Raman bands as a function of the annealing temperature. The Raman intensity is normalized by the effective film thickness (see Section 3.2). Reproduced with permission from [118]. Copyright Wiley-VCH Verlag GmbH & Co. KGaA.
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Upon annealing at 1000 °C, a narrow Raman band at ~516–517 cm–1 emerges for both types of samples, showing the formation of Si-nc. As compared to the as-prepared samples, the absorption coefficient of the annealed samples is increased for ion implantation but it is decreased for MBD (Figure 8a). After annealing at 1100–1200 °C, both types of samples become optically and structurally more similar. For both types of samples, the Raman band is observed at ~518 cm–1 and the absorption coefficients become closer (Figure 8). These trends are reasonably explained by growth and crystallization of Si clusters in the implanted sample and by crystallization of amorphous clusters in the MBD sample. Indeed, the extinction coefficient of crystalline Si is much smaller than that of amorphous Si.
After annealing (>1000 °C), the normalized Raman intensity and the absorption coefficient are larger for the MBD samples compared to the ion-implanted sample (Figure 8). This result indicates that the amount of Si-nc with diameters of ≥2 nm is greater in the MBD films. This conclusion is also supported by a smaller band gap for the MBD sample (~2.6 eV) compared to that for the implanted sample (~3.3 eV). For both types of samples, a substantial amount of suboxides (~15%) is detected by XPS even after annealing at 1200 °C, indicating that the Si–SiO2 phase separation is not complete.
For annealing below 900 °C, the PL maximum is located at about 650–700 nm for both types of samples, and the PL intensity is much higher for the implanted sample (Figure 9). The latter fact indicates a larger amount of thermodynamically unstable radiative defects in the implanted sample [31,32,130,131,132]. Annealing at ~1100 °C enhances the 1.5-eV PL for both types of samples. After this annealing, the normalized PL is slightly stronger for the implanted sample (Figure 9), which is remarkable because the Raman band of Si-nc is weaker for this preparation method (Figure 8b). Annealing at 1200 °C weakens the PL, and this effect is more pronounced for the implanted sample. This decrease of the PL can originate from a thermal modification of the light-emitting centers, for example, an increase of the size of oxidized ultra-small Si grains. In the case of the implanted samples, this conclusion is supported by the redshift of the PL to ~900 nm and by the decrease of the band gap from 3.3 to 2.8 eV for annealing at 1150 and 1200 °C, respectively.
Figure 9. PL spectra of as-prepared (ap) and annealed (1100 °C) SiO1.8 films fabricated by MBD and ion implantation. The PL spectra are normalized by the effective film thickness (see Section 3.2). Reproduced with permission from [118]. Copyright Wiley-VCH Verlag GmbH & Co. KGaA.
Figure 9. PL spectra of as-prepared (ap) and annealed (1100 °C) SiO1.8 films fabricated by MBD and ion implantation. The PL spectra are normalized by the effective film thickness (see Section 3.2). Reproduced with permission from [118]. Copyright Wiley-VCH Verlag GmbH & Co. KGaA.
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2.1.4. Laser Heating of Films on Substrates

Laser light is found to increase the temperature of SiOx films on silica substrates [116]. For example, 488-nm laser power of ~130 mW focused to a ~40-μm spot (laser intensity ~104 W cm–2) leads to a temperature of ~350 °C in a SiO1.3 film annealed at 1100 °C. The absorption coefficient of this film increases at 350 °C by ~40% compared to the room temperature value, which is probably due to the thermally induced shrinking of the bang gap [97]. At this laser-induced temperature, the Raman band of Si-nc is observed at ~512.5 cm–1, i.e., it is down-shifted by ~6 cm–1 from the room temperature position. The temperature dependence of the Raman shift (Figure 10a) is in excellent agreement with the calculations by Faraci et al. for Si-nc with sizes of 5 nm [138]. Similar temperature dependences were previously reported for crystalline Si [139] and the free-standing SiO1.7 film [95]. The phonon confinement effect and residual stresses can explain the quantitative differences between the Raman band positions in these cases.
Figure 10. (a) Raman shift as a function of the laser-induced temperature and (b) Laser-induced temperature as a function of the absorbed laser power. The measurements are made for a SiO1.3 film on a silica substrate annealed at 1100 °C using various 488-nm laser intensities (solid circles) and for SiOx films (1.3 < x < 1.5) at the maximum laser intensity of ~104 W cm–2 (open circles) [116]. The data for a free-standing SiO1.7 film [95] (FSF, triangles) and for crystalline Si [139] (solid line) are shown for comparison. The dashed line in panel b is a linear fit. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
Figure 10. (a) Raman shift as a function of the laser-induced temperature and (b) Laser-induced temperature as a function of the absorbed laser power. The measurements are made for a SiO1.3 film on a silica substrate annealed at 1100 °C using various 488-nm laser intensities (solid circles) and for SiOx films (1.3 < x < 1.5) at the maximum laser intensity of ~104 W cm–2 (open circles) [116]. The data for a free-standing SiO1.7 film [95] (FSF, triangles) and for crystalline Si [139] (solid line) are shown for comparison. The dashed line in panel b is a linear fit. Reproduced with permission from [116]. Copyright 2012, AIP Publishing LLC.
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Figure 10b shows the laser-induced temperature for a free-standing SiO1.7 film and SiOx films (1.3 ≤ x < 1.5) on silica substrates as a function of the laser power absorbed by a unit volume, which is proportional to ( 1 e α d ) P d , where P is the laser power, α is the absorption coefficient, and d is the film thickness [95]. The linear fit of the temperature versus the absorbed power yields the room temperature at zero power, which verifies the results. For the same absorbed power, the laser-induced temperature is much higher in the free-standing films compared to the films on substrates, which is due to the thermal flow to the substrate in the latter case.
In Raman measurements of Si-nc, relatively high laser powers are usually employed to obtain a good signal-to-noise ratio. It follows that the laser-induced heat should always be carefully considered even for films on substrates (especially when using Raman microscopes) to obtain reliable information of the material structure. In general, laser heat, local stress, and phonon confinement are overlapping effects with respect to the Raman spectra.

2.2. Laser Annealing of Free-Standing Films

2.2.1. Laser-Annealed Areas

We have studied CW laser annealing (488 nm) of free-standing SiOx films (0.5 and 2 μm-thick) and Si/SiO2 SL (0.5-μm-thick). After preparation (Section 3.1), the free-standing films presumably contain small Si-nc (up to 4 nm in diameter) [95,125]. The laser annealing is usually performed for ~1 s in air atmosphere (if different is not stated). An optical photograph of a typical laser-annealed area on a free-standing film and a Raman map from the same area are presented in Figure 11. Three regions can be distinguished: (i) central region, (ii) ring around the central region, and (iii) pristine film outside the irradiated area [140,141,142].
Figure 11. (a) Optical microscope photograph and (b) Raman map of the Si-nc band. A 2-μm-thick free-standing SiOx film (x ~ 1.7–1.8) is exposed to 488-nm light (~110 mW) through a lens (focal length of 150 mm). In the optical photograph, the sample is illuminated through the objective. The oval shape is due to a non-perpendicular direction of the annealing laser beam. Brighter regions in the Raman map correspond to stronger Raman signals. The Raman signal is integrated in the 510–540 cm–1 spectral range. Reproduced with permission from [140]. Copyright 2010, AIP Publishing LLC.
Figure 11. (a) Optical microscope photograph and (b) Raman map of the Si-nc band. A 2-μm-thick free-standing SiOx film (x ~ 1.7–1.8) is exposed to 488-nm light (~110 mW) through a lens (focal length of 150 mm). In the optical photograph, the sample is illuminated through the objective. The oval shape is due to a non-perpendicular direction of the annealing laser beam. Brighter regions in the Raman map correspond to stronger Raman signals. The Raman signal is integrated in the 510–540 cm–1 spectral range. Reproduced with permission from [140]. Copyright 2010, AIP Publishing LLC.
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In the central region, the material is essentially amorphous SiO2. For 0.5-μm-thick SiOx films (x ~ 1.7–1.8), this composition is directly shown by XPS and electron energy loss spectroscopy (EELS) [140]. In accord, the TEM images and selected area diffraction (SAD) patterns indicate a very homogeneous and amorphous structure of this region, and the Fourier-transform infrared spectra (FTIR) measured with high spatial resolution are similar to those of thermal silica. In this region, no Si-related peak is detected by Raman spectroscopy, the absorption is very low, and no PL is observed (Figure 12). In agreement, for 0.5-μm-thick Si/SiO2 SL (2-nm-thick Si and SiO2 layers), no Si clusters are detected in bright-field scanning TEM (BF-STEM) images, and energy-dispersive X-ray spectroscopy (EDS) indicates an increase of x in the central region compared to the pristine film [141,142]. Quantitative analysis based on the EDS measurements is not possible because quantification using low-energy X-ray lines such as oxygen K alpha is not feasible. Small Si clusters (<1 nm) invisible by these microscopic methods are in principle possible in the central region. However, very small Si clusters are thermodynamically unfavorable [143], and their formation seems to be improbable at high temperatures. Furthermore, these very small Si grains are presumably luminescent; however, practically no PL is detected from the central region.
Figure 12. (a) Raman spectra of a laser-annealed 2-μm-thick SiOx (x ~ 1.7–1.8) film from regions in the center (in), on the ring (on), and outside the laser-annealed area (out). (b) Raman (circles), PL (stars), and transmission (triangles) cross-sections of the laser-annealed area. The cross-sections are measured in the vertical direction through the center of the laser-annealed area shown in Figure 11. Reproduced with permission from [140]. Copyright 2010, AIP Publishing LLC.
Figure 12. (a) Raman spectra of a laser-annealed 2-μm-thick SiOx (x ~ 1.7–1.8) film from regions in the center (in), on the ring (on), and outside the laser-annealed area (out). (b) Raman (circles), PL (stars), and transmission (triangles) cross-sections of the laser-annealed area. The cross-sections are measured in the vertical direction through the center of the laser-annealed area shown in Figure 11. Reproduced with permission from [140]. Copyright 2010, AIP Publishing LLC.
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In the ring around the central region, the EFTEM, BF-STEM, and TEM images evidence large Si-nc embedded in amorphous SiO2 (Figure 13) [140,141,142]. The maximum Si-nc diameters (~200 nm) for the 0.5-μm-thick Si/SiO2 SLs [141] are on average two times larger than those detected for the 0.5-μm-thick free-standing SiOx films (x ~ 1.7–1.8) [140]. This difference is reasonably explained by a larger Si content in Si/SiO2 SLs (x ~ 0.7 from the deposition conditions) compared to the SiOx films (x ~ 1.7–1.8). The crystallinity of the large Si clusters in the ring region is confirmed by selected-area diffraction measurements (for 0.5-μm-thick SiOx film) and Raman spectroscopy. The Raman band is quite narrow and does not have a shoulder at 450–500 cm–1, indicating the absence of amorphous phase and therefore suggesting efficient Si crystallization (see Figure 12a). The EELS spectra show the presence of the Si and SiO2 phases. In accord, the FTIR spectra correspond to stoichiometric SiO2 perturbed by the Si–SiO2 interface. The Raman bands from the ring region is stronger by about 2–3 orders of magnitude compared to the pristine film, which is explained by the resonance size effect for the large Si-nc [144]. The Raman bands from Si-nc in the ring region are typically shifted up to ~530 cm–1 (from the value of 521 cm–1 for crystalline Si) indicating a compressive stress on Si-nc. According to the mechanism proposed earlier [56], these large Si-nc are formed from the liquid phase, and the stress appears when their volume suddenly increased in the solid SiO2 matrix. Thus, the temperature in the ring region exceeds the melting point of Si (1685 K). Indeed, a temperature of ~2000 K was estimated by fitting the strong light-emission background upon irradiation with high laser intensities (~16 kW cm–2 at the sample) [94]. The bright thermal radiation is also seen by the naked eye. High processing temperatures in the central region are also confirmed by the decrease of the film roughness detected by AFM. For 0.5-μm-thick Si/SiO2 SLs, scanning electron microscopy (SEM), TEM, and atomic force microscopy (AFM) show several large holes (up to 200 nm) in the inner part of the ring region (Figure 13a,b).
These results demonstrate a Si–SiO2 phase separation on a macroscopic scale. The central region (up to 30 μm) is cleaned of the Si excess. On the other hand, in the ring region, large Si-nc are formed and the Si excess is enhanced as found for 0.5-μm-thick SiOx film by XPS and EELS [140]. The macroscopic phase separation can be explained as follows [140]. In the beginning of laser irradiation, the film structure is homogeneous so that the temperature gradient approximately corresponds to the intensity gradient in the Gaussian beam. The temperature gradient gives rise to a concentration gradient due to different diffusion properties of the mixture constituents. For example, Si, O, and SiO can diffuse in silica [145], which changes the relative concentrations. Diffusion in temperature gradient is known as thermodiffusion or Ludwig-Soret effect [146,147]. As detected by EELS, XPS, and AFM, the central region is typically thinner than the pristine film by about 30%–40% and ~50% for 0.5-μm-thick Si/SiO2 SLs and SiOx films, respectively. Moreover, AFM shows an increase of the film thickness in the ring region compared to the pristine film [142]. These results are also indicative of macroscopic movement of Si excess from the central region.
Figure 13. TEM images of a 0.5-μm-thick Si/SiO2 SL showing a Si particle located near the film surface (marked with a white arrow). The images in (a), (b), and (c) are taken with different magnification. (c) shows this particle in the tilt geometry, the surface subparticle being indicated by a dotted circle. The bright spots are holes in the film; the holes observed in (b) are marked by black arrows in (a). Figure courtesy of Simona Boninelli and Fabio Iacona. Reproduced with permission from [141]. Copyright 2012, AIP Publishing LLC.
Figure 13. TEM images of a 0.5-μm-thick Si/SiO2 SL showing a Si particle located near the film surface (marked with a white arrow). The images in (a), (b), and (c) are taken with different magnification. (c) shows this particle in the tilt geometry, the surface subparticle being indicated by a dotted circle. The bright spots are holes in the film; the holes observed in (b) are marked by black arrows in (a). Figure courtesy of Simona Boninelli and Fabio Iacona. Reproduced with permission from [141]. Copyright 2012, AIP Publishing LLC.
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2.2.2. Surface Structure

For laser-annealed 0.5-μm-thick Si/SiO2 SLs, surface analysis (SEM and AFM) has been used to discriminate Si-nc located near the film surface [141]. In the tilt TEM images (Figure 13c), these “surface Si-nc” have an unusual pear-like shape with the thinner part presumably sticking out of the laser-illuminated surface. The AFM and SEM methods estimate that the thinner part above the surface (surface feature) has a typical size of 60–70 nm, in agreement with the TEM measurements. The subsurface part has a diameter of ~200 nm, as shown by TEM and BF-STEM images.
The formation of the surface features is explained by the following mechanism. Since most of large Si-nc formed by laser annealing are under high compressive stress, it is possible that the laser-pressurized silicon can erupt from the film if it is separated from the ambient atmosphere by a very thin silica layer. The erupted Si is seen as the subparticle in Figure 13c. The volume of the subparticle (~70 nm in diameter) is ~5% of the volume of the larger subsurface part of the nanocrystal (~200 nm in diameter). Eruption of this volume would lead to a substantial decrease of the compressive stress of the parent particle [56]. The fact that no eruptions are detected on the backside of the film seems to be consistent with this mechanism. Indeed, the temperature should be somewhat higher on the front (laser-illuminated) side of the film; hence, the covering silica film is softer here, which favours Si eruption.
Raman measurements confirm the proposed eruption model. The surface Si nanocrystal shown in the TEM images in Figure 13 is located in position 1 in Figure 14a. The Raman shift obtained in this position is ~520 cm–1 (spectrum 1, Figure 14b), which indicates a low stress. It is reasonable that Si eruption can relax stress in the vicinity of surface Si-nc. The compressive stress is partially relaxed at a distance of about 1 µm from the surface feature (spectrum 2). The Raman spectrum measured at position 3, which is far away from the surface feature, shows a higher compressive stress (spectrum 3 in Figure 14b).
Figure 14. Raman characterization of the area shown in Figure 13a. (a) Raman map of Si-nc (integration from 515 to 530 cm–1) obtained with a 100× objective and steps of 0.2 μm. Brighter areas correspond to stronger Raman signals. The white circles indicate the positions of two holes used as the reference points. (b) Raman spectra in positions 1, 2, and 3 indicated in (a). Position 1 corresponds to the surface Si-nc shown in Figure 13. Reproduced with permission from [141]. Copyright 2012, AIP Publishing LLC.
Figure 14. Raman characterization of the area shown in Figure 13a. (a) Raman map of Si-nc (integration from 515 to 530 cm–1) obtained with a 100× objective and steps of 0.2 μm. Brighter areas correspond to stronger Raman signals. The white circles indicate the positions of two holes used as the reference points. (b) Raman spectra in positions 1, 2, and 3 indicated in (a). Position 1 corresponds to the surface Si-nc shown in Figure 13. Reproduced with permission from [141]. Copyright 2012, AIP Publishing LLC.
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2.2.3. Effect of the Annealing Atmosphere

The studies described above have been performed in the atmosphere of air (containing ~20% of oxygen), which can cause some oxidation of Si during laser annealing. Indeed, oxygen can diffuse through the film oxide to Si-nc [148,149,150]. This process may decrease the excess of Si, especially in the central region, where the temperature in the beginning of laser annealing is the highest. To evaluate this effect, we compare laser annealing in atmospheres containing different amounts of oxygen (Ar, N2, O2, and air). Detailed measurements are performed for 0.5-μm-thick Si/SiO2 SL and 1-s exposure [142].
For all annealing atmospheres, the central region of laser-annealed areas most probably consists of amorphous silica without Si excess. This composition is indicated by the absence of the Raman signal of Si in this region, an increase of x compared to the pristine film detected by EDS, and the absence of Si clusters in the BF-STEM images. In the ring region, large Si-nc (up to 150–300 nm) are formed, and the film thickness tends to increase compared to that of the pristine film. The change of the film thickness was estimated using the AFM images taken from both sides of the film. These results support the concept of macroscopic Si–SiO2 phase separation as a result of laser annealing.
The effect of oxygen can be analyzed by comparing the film thickness in the central region obtained for different atmospheres. Indeed, two competitive processes, thermodiffusion and Si oxidation, affect the film thickness in the opposite directions, tending, respectively, to decrease and to increase it. For Ar atmospheres, the central region is thinner by ~150 nm than the pristine film, i.e., the thickness is about 350 nm. This observation supports the concept of the macroscopic phase separation because Si oxidation does not operate in the inert atmospheres. A similar change of the thickness occurs in air (the thickness of the central region is 300–350 nm) also indicating minor Si oxidation.
In contrast, laser annealing in pure O2 increases the film thickness in the central region by ~20 nm compared to the pristine film. Thus, both thermodiffusion and Si oxidation seem to operate in this case, practically compensating each other. It seems that a significant part of Si is oxidized upon laser annealing in pure oxygen. The difference between the film thickness of the central region for inert and O2 atmospheres is ~200 nm (larger in oxygen). 200 nm of SiO2 can be formed by oxidation of about 100-nm Si layer, which corresponds to ~40% of all amount of elemental Si in the pristine SL (125 2-nm-thick Si layer). According to the model suggested by Deal and Grove for crystalline Si, 1 bar of dry O2 at 1200 °C produces ~20-nm oxide film during 1 s, whereas a ~33-nm oxide is formed for 100 s [149], which is in approximate agreement with our estimates. It should be reminded that the temperature of laser annealing is sufficiently higher [94]. In addition, the extent of oxidation can differ from these values because our pristine material is very different from crystalline Si.
The structure of the ring region is also affected by the amount of O2 in the ambient atmosphere. For inert atmospheres, the AFM and BF-STEM images show that the ring region is very inhomogeneous. It has areas with large Si-nc (up to 150 nm in diameter), with large non-spherical holes up to 300 nm, and with smaller Si-nc (up to 50 nm in diameter). No surface Si-nc are observed in this case, as shown by AFM and SEM. Raman spectroscopy indicates Si-nc with different stresses (Raman shifts from 518 to 530 cm–1) and regions with very different intensities of Raman bands of Si-nc. The BF-STEM images show a “belt” of nano-channels (or pores) around the ring region. The size of these nano-channels can be as low as several nanometers.
For laser annealing in air, the ring region contains Si-nc with diameters of up to 200 μm. A chain of holes with sizes up to 200 μm is seen at the inner part of the ring of large Si-nc (Figure 15a). A number of surface features are observed as discussed above.
For pure O2 atmosphere, in addition to Si-nc inside the film, SEM and AFM show a regular chain of surface features that are located in the inner part of the ring at the front side of the film (Figure 15b). The undersurface part of the surface Si-nc can be up to 300 nm in diameter. In agreement with the suggested eruption model, Raman spectroscopy shows a relaxed stress for these surface Si-nc (Raman shift of ~520 cm–1) whereas the Si-nc at the outer part are still under compressive stress (Raman shift up to ~530 cm–1). No holes in the film are observed after laser annealing in O2 atmosphere.
Figure 15. Secondary electron (SE) images of the front side of laser-annealed areas produced in (a) air and (b) O2 atmospheres during 1-s exposure. Surface features are white, holes are black. The scale is the same in both panels. Figure courtesy of Marianna Kemell. Reprinted with permission from [142]. Copyright 2014, American Scientific Publishers.
Figure 15. Secondary electron (SE) images of the front side of laser-annealed areas produced in (a) air and (b) O2 atmospheres during 1-s exposure. Surface features are white, holes are black. The scale is the same in both panels. Figure courtesy of Marianna Kemell. Reprinted with permission from [142]. Copyright 2014, American Scientific Publishers.
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Based on these results, it can be suggested that the holes produced in inert and air atmospheres are formed via removal of surface Si-nc from the film. For laser annealing in air, the holes appear in the positions where a chain of large surface Si-nc is observed in the case of O2 atmosphere (see Figure 15). The laser-annealed areas with larger number of holes contain less surface Si-nc, and the presence of oxygen increases the amount of surface Si-nc. This observation suggests that oxygen decreases the removal of large Si-nc by the formation of a thin oxide layer covering surface Si-nc, which “glues” them to the film. The large irregular holes obtained in the inert atmospheres also presumably originate from large Si-nc removed from the film. The suggested mechanism of hole formation is consistent with the dependence of the maximum Si-nc sizes on the annealing atmosphere. For inert atmospheres, the largest Si-nc visible in the BF-STEM images are “only” ~150 nm in diameter because bigger Si-nc are removed from the films forming holes with sizes of up to 300 nm. For O2 atmosphere, the largest Si-nc (up to 300 nm) are detected because they are protected by thin oxide layers. Annealing in air represents an intermediate case where the largest Si-nc are ~200 nm in diameter, and some Si-nc are removed forming holes. In accord, with the proposed mechanism, holes are not observed in a 0.5-μm-thick SiOx film (x ~ 1.7–1.8) annealed in air [140]. For this film, Si-nc have diameters “only” up to 100 nm, which are substantially smaller than the film thickness. These Si-nc are mostly located below the film surface and, hence cannot be removed to form holes.
Figure 16 shows the cross-sections of the Raman signal measured through characteristic ring regions of the laser-annealed areas prepared in inert (Ar) and O2 atmospheres. For inhomogeneous ring regions formed in Ar atmosphere, two different characteristic cross-sections are observed (Figure 16a,b) whereas for O2 and air atmospheres, the laser-annealed area is more uniform having similar Raman cross-sections in different ring regions (see Figure 16c for O2). For 488-nm laser light, the Raman enhancement is known to be the strongest for spherical Si particles with diameters of ~112.5 nm [144]. In agreement, Si-nc with sizes ~100 nm are observed in the areas with the strongest Raman signal (at coordinate = 0). At coordinates >5 μm, the Raman spectra are similar to that of the pristine film. In Figure 16b, the Raman intensity is relatively weak in the ring region because the Si-nc diameters in this case do not exceed ~50 nm, which is smaller than the resonance value of ~112.5 nm.
For inert atmospheres (Figure 16a,b), the Raman signal is very weak at coordinates 2–3 μm. For air and O2, this decrease of Raman intensity is less pronounced but still observable (Figure 16c). We call this effect the secondary Si depletion, and it supports the model of macroscopic phase separation. We tentatively explain the formation of this interval with low Raman intensity in the following way. When the large Si-nc are formed in the ring region during laser annealing, the absorption coefficient in this area strongly increases resulting in an increase of the temperature. Due to the thermal conductivity, the temperature of the vicinity also increases, which leads to a temperature gradient and additional macroscopic phase separation outside the ring region. This process seems to be more efficient for the inert compared to oxygen-containing atmospheres. The position of this spatial interval roughly coincides with the position of the belt of nano-pores and nano-channels observed by SEM in the inert atmospheres. The exact mechanism of the formation of these pores is unclear.
Figure 16. Characteristic Raman cross-sections of the ring region. Two characteristic cross-sections (a) and (b) are shown for Ar atmosphere, and the cross-sections (c) are similar for O2. For air, the cross-sections are similar to the case of O2. The Raman signal is integrated in the 230–585 cm–1 range. The data are normalized by the Raman intensity measured from the pristine film. Reprinted with permission from [142]. Copyright 2014, American Scientific Publishers.
Figure 16. Characteristic Raman cross-sections of the ring region. Two characteristic cross-sections (a) and (b) are shown for Ar atmosphere, and the cross-sections (c) are similar for O2. For air, the cross-sections are similar to the case of O2. The Raman signal is integrated in the 230–585 cm–1 range. The data are normalized by the Raman intensity measured from the pristine film. Reprinted with permission from [142]. Copyright 2014, American Scientific Publishers.
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2.2.4. Effect of the Exposure Period

Laser annealing with different exposures (10 ms and 100 s, in addition to 1 s) has been studied for 0.5‑μm-thick Si/SiO2 SL mostly in air atmosphere [142]. For the central area, the results are similar for all exposures: the EDS measurements show an increase of x (relative to the pristine film), no Raman signal from Si-nc is detected, and no Si clusters are visible in the BF-STEM images. Thus, 10-ms exposure is enough for the removal of excess Si from the central region. In other words, the formation of the central region occurs in a millisecond time scale.
On the other hand, the ring region differs for different exposures. For 10-ms exposures, no holes and surface features are found and Si-nc have diameters of up to 20–30 nm. For 1-s and 100-s laser exposures, some holes and surface features are formed and Si-nc with diameters up to 200 and 250 nm, respectively, are observed. Thus, longer laser exposure increases the Si-nc size. Coalescence of Si-nc can be suggested for this process [73], because the number of Si-nc decreases for longer exposure periods. The increase of the Si-nc sizes with the exposure period can probably explain the greater amount of surface Si-nc observed for 100-s compared to 1-s exposure. For other atmospheres, the prolonged laser annealing (100 s) also decreases the amount of small Si-nc and increases the average sizes of Si-nc compared to 1-s exposure.
The Si-nc diameters for 10-ms exposure (20–30 nm) are smaller than the resonance size of 112.5 nm. This explains why no Raman enhancement is observed from these Si-nc (Figure 17). In contrast, for 1-s and 100-s exposures, the Raman intensity is strongly enhanced compared to that from the pristine film, which is explained by the presence of Si-nc with diameters of ~100 nm. The Raman band observed after 10-ms exposure has a smaller low-frequency shoulder compared to the pristine film, meaning that the amount of disordered Si and/or small Si clusters is reduced. As the exposure increases, the Raman band narrows indicating that the structure of Si-nc becomes more regular. For 100-s exposure, the width of the Si-nc Raman band is as narrow as that of a crystalline Si wafer, which indicates an almost perfect crystalline structure.
For 10-ms and 1-s exposures, the Si-nc in the ring region are under compressive stress because the Raman shifts are larger than that of crystalline Si (Figure 17); thus, these Si-nc are formed from the liquid phase. On the contrary, no stress on Si-nc is detected for 100-s exposure for all studied annealing atmospheres. This fact may show that for the long exposure, the temperature of large Si-nc becomes at some moment below the melting point. The decrease of the temperature for long exposure may be explained by the decrease of the absorption when the Si-nc become much larger than the resonance size of 112.5 nm [144]. Annealing at temperatures below the melting point relaxes the stress [56,96].
Figure 17. Typical Raman spectra of the ring region for 10-ms, 1-s, and 100-s exposures in air. Raman spectra of the pristine film and crystalline Si wafer (cSi) are also shown. Reprinted with permission from [142]. Copyright 2014, American Scientific Publishers.
Figure 17. Typical Raman spectra of the ring region for 10-ms, 1-s, and 100-s exposures in air. Raman spectra of the pristine film and crystalline Si wafer (cSi) are also shown. Reprinted with permission from [142]. Copyright 2014, American Scientific Publishers.
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2.2.5. Optical Memory

We describe two concepts of optical memory based on laser annealing of Si nanostructures in free-standing Si/SiO2 SLs [151]. The first concept is based on the enhancement of Raman signal. The sample is irradiated by a 488 nm laser beam focused by a 100× objective of a Raman microscope, which produces laser-annealed areas with sizes below 1 μm. These areas are clearly visible in camera photographs (Figure 18a), and this indicates a change in the reflection and/or absorption coefficient of the film. The Raman, PL, and transmission profiles through a typical laser-annealed spot are presented in Figure 18b.The Raman signal is strongly enhanced whereas the transmission is decreased due to temperature-induced Si–SiO2 phase separation and ordering and growth of Si-nc [140,141,142].
Figure 18. Writing digital data on a free-standing 2-μm-thick Si/SiO2 SL. (a) Camera photograph of three spots produced by 488-nm laser annealing for ~10 ms. (b) Cross-section of the Raman, transmission, and 1.5-eV PL signals through a typical laser spot. (c) Cross-section of the Raman intensity through the spots presented in panel a, which illustrates digital data points. The Raman intensity is integrated in the 500–540 cm−1 range. Reproduced with permission from [151]. Copyright 2009, AIP Publishing LLC.
Figure 18. Writing digital data on a free-standing 2-μm-thick Si/SiO2 SL. (a) Camera photograph of three spots produced by 488-nm laser annealing for ~10 ms. (b) Cross-section of the Raman, transmission, and 1.5-eV PL signals through a typical laser spot. (c) Cross-section of the Raman intensity through the spots presented in panel a, which illustrates digital data points. The Raman intensity is integrated in the 500–540 cm−1 range. Reproduced with permission from [151]. Copyright 2009, AIP Publishing LLC.
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The observed laser effect is a case of non-volatile memory. Binary digits can take values of either 0 or 1 as demonstrated in Figure 18c. The smaller Raman intensity corresponds to 0, whereas the higher Raman intensity represents 1. Similar data reading can be obtained by transmission or reflection measurements. The estimated data density for this method is ~1 bit/μm2, which can be improved by using stronger objectives and shorter laser wavelength. The nature of the used material provides high thermal stability of the described optical memory. The thermal stability of the laser-crystallized spots was tested by furnace annealing for 1 h at 1200 °C in a nitrogen atmosphere. As expected, Raman and transmission signals remained unchanged. This approach does not allow erasing and rewriting information.
The second concept is based on Si-nc stress. First, a free-standing Si/SiO2 SL is shortly irradiated with a relatively large laser spot (10–40 μm in diameter), which produces an extended area with a compressive stress of ~3 GPa (see Figure 11). This stress is evidenced by Raman bands at ~527 cm−1 (Figure 19a). Next, the stressed area is irradiated by a highly focused laser beam using a 100× objective and reduced laser power. As a result of laser annealing below the Si melting temperature, the stress is released in the irradiated spot and the Raman band shifts down to ~518 cm–1. The typical size of the spot with relaxed stress is ~1 μm (Figure 19b). The optical constants are practically unchanged upon the stress relaxation, and this effect is invisible in optical photographs. The laser-induced decrease of the Raman shift writes data pixels on the film similarly to the concept based on the Raman enhancement. The data can be erased by inducing stress using a broad laser beam and then re-written again. The retention time of the stress-based memory is estimated to be about 1 year at ~300 °C [56].
Figure 19. (a) Raman spectra of Si-nc with stress of ~3 GPa and after laser-induced relaxation (for 2-μm-thick Si/SiO2 SL). (b) Cross-sections of the Raman band position and Raman intensity integrated in the 510–520 cm−1 region. Reproduced with permission from [151]. Copyright 2009, AIP Publishing LLC.
Figure 19. (a) Raman spectra of Si-nc with stress of ~3 GPa and after laser-induced relaxation (for 2-μm-thick Si/SiO2 SL). (b) Cross-sections of the Raman band position and Raman intensity integrated in the 510–520 cm−1 region. Reproduced with permission from [151]. Copyright 2009, AIP Publishing LLC.
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3. Experimental Section

3.1. Samples

Most of the samples used in this study have been prepared by MBD in the Aalto University (Finland) by S. Novikov. The SiOx films are deposited on silica wafers. Some of the samples have a gradient of the Si content in the lateral direction, and they are called optical wedges. Due to the deposition conditions, these films also have a varying thickness (1.5–2.5 μm). The advantage of the optical wedges is that the areas with different Si contents are annealed under the same conditions and the O/Si concentration ratio x can be continuously changed by selecting the film area. The wedged samples are cut in slices (5–7 cm long and ~1 cm wide) along the Si content gradient and annealed in a furnace at temperatures up to 1200 °C for 1 h in nitrogen atmosphere. In [116], three samples covering x from ~1.3 to ~1.98 are studied.
The free-standing films are prepared from the SiOx films and Si/SiO2 SL sdeposited on Si wafers and annealed in a furnace at 1100 °C in nitrogen atmosphere. The free-standing films are made by chemical etching of the Si substrate [125,140,141,142]. The Si/SiO2 SLs are constituted of 125 or 500 pairs of 2-nm-thick Si and SiO2 layers, yielding the total film thicknesses 0.5 or 2 μm, respectively. The thicknesses of the free-standing SiOx films (x ~ 1.7–1.8) are 0.5 and 2 μm.
One sample is made by Si-ion implantation into a silica substrate in the Accelerator Laboratory (University of Helsinki) [118]. The implantation of Si ions into a silica plate was done with different energies (30, 56, 98, 160, 250, and 400 keV) and doses to achieve a nearly constant Si excess in the SiOx layer with a thickness of ~750 nm. The O/Si concentration ratio x estimated by XPS is ~1.8. The implanted sample is annealed at various temperatures up to 1200 °C for 1 h in a nitrogen atmosphere.

3.2. Equipment

The main analytical techniques used in our laboratory are Raman, PL, and UV-visible absorption methods. Two setups have been used to record the Raman and PL spectra. The first setup consists of an argon-ion laser (488 nm, Melles Griot 543-AP-A01), a spectrometer (Acton SpectraPro 500I), and a charge-coupled device camera (Andor InstaSpec IV). The laser beam is focused with a lens to a spot with a diameter of ~40 μm. The second setup allows us to perform micro-Raman and micro-PL measurements. It consists of a confocal Raman microscope (LabRAM HR800, Horiba Jobin Yvon) equipped with an argon-ion laser (488 nm). The size of the laser spot in the microscopic measurements is down to ~1 μm. For both setups, the spectral resolution is ~2 cm−1 and 10 cm−1 for Raman and PL measurements, respectively. The Raman bands of the films annealed at ≥1000 °C are fitted with two or three Gaussians. The position of the Raman band of Si-nc is obtained from the position of the higher-frequency Gaussian (~518–530 cm–1). The PL spectra are corrected for the spectral sensitivity of the apparatus. The Raman and PL intensities are normalized by the effective thickness 0 d e ( 2 a x ) d x and 0 d e ( a x ) d x , respectively, where the same absorption coefficients α is assumed for the laser and Raman light, the absorption for the PL is neglected, and d is the film thickness [55].
Laser annealing of free-standing films is performed using a TEM00 beam of an argon-ion laser (488 nm, power up to 110 mW at the sample) focused to spots with diameters ranging from ~1 to ~40 μm. The exposure time is mainly ~1 s, but 10-ms and 100-s exposures is also used in some experiments. Most of laser-annealing studies are performed in air; however, a number of measurements are done in O2, N2, and Ar atmospheres.
The absorption coefficient is obtained from the transmission and reflection spectra [152], recorded with a fiber-optics spectrometer (SD2000, Ocean Optics) and a broadband light source (DH-2000, Top Sensor Systems) or by measuring transmitted and reflected laser light using a power meter (NOVA II, OPHIR). The micro-transmission measurements of the 488-nm light are carried out in the LabRAM microscope with a large-area photodiode located behind the sample.
Additional measurements by other methods have been available from cooperation: XPS [115,116,117,118] including measurements with high spatial resolution [140], FTIR spectroscopy with high spatial resolution [140], TEM including bright-field scanning (BF), STEM and EFTEM [140,141], EELS [140], SEM and EDS [141,142], AFM [141,142], and m-line measurements [115]. The equipment used in these methods is described in the given references.

3.3. PL-Filtering Effect

The method to measure the optical properties of the films utilizes the PL-filtering effect. The PL filtering is observed when the PL spectra are measured in a direction along the film surface. In this case, narrow and polarized spectral peaks are detected (Figure 20a). The PL filtering has been observed in various silica films containing Si-nc [49,57,59,79,85,86,87,94].
The PL-filtering effect can be interpreted in terms of delocalization of guided modes near the cut-off frequency [49,57,79,85]. The minimal losses occur near the cut-off wavelengths, for which the delocalized light travels mostly in the transparent substrate rather than in the absorbing film. Thus, the narrow peaks seen in the PL spectra obtained in the waveguiding direction correspond to the cut-off wavelengths. The mode localization is a function of the generalized frequency parameter written for an asymmetrical planar waveguide in the form:
V = 2 π ( n 1 2 n 2 2 ) d / λ
where n 1 and n 2 are the refractive indexes of the film and substrate, respectively, d is the film thickness, and λ is the wavelength. This equation is obtained assuming weak-guiding approximation ( n 1 n 2 ) 1 [127]. For the cut-off condition V = ( 2 m + 1 ) π / 2 , Equation (1) yields the cut-off wavelengths.
Figure 20b shows a typical transmission spectrum of an annealed SiO1.5 film on a silica substrate. The spacing of the interference patterns (in cm–1) can be written as:
δ ν = 1 / 2 n 1 d
which provides the optical thickness (nd). The numerical information can be extracted from the transmission spectrum by fitting it, for example, with the following empirical function:
T ( λ ) = P 7 + P 1 ( 1 P 3 λ P 2 ) [ 1 P 4 sin ( P 5 λ + P 6 ) ]
where T is the transmittance, and Pi are the fitting parameters [49]. In particular, the P5 parameter is connected with the period of the oscillations, i.e., with the optical thickness. The TE refractive index is relevant to transmission spectra. By using Equation (1) for the spacing between the TE peaks and Equation (2), the TE refractive index and the film thickness can be extracted [85]. Next, the obtained layer thickness together with the spacing between the TM peak positions is used to calculate the TM refractive index. The obtained thickness is also used to calculate the absorption (extinction) coefficient from the transmission and reflection measurements.
The model described above is called a simple model because it uses a few simplifications: (i) Equation (1) corresponds to the weak-guiding approximation ( n 1 n 2 ) 1 ; (ii) the procedure uses only the interval between the cut-off peaks disregarding their actual positions; (iii) the material dispersion is neglected; and (iv) a step-like profile is assumed for the refractive index.
Figure 20. (a) Cut-off spectra of a SiO1.5 film annealed at 1100 and 1200 °C, measured from the sample edge along the film. The excitation spot was at a distance of several millimeters from the sample edge. The positions of the TE peaks are marked and the other bands have the TM polarization. The TE and TM peaks have polarization parallel and perpendicular to the film surface, respectively. (b) Transmission spectrum of the SiO1.5 film annealed at 1100 °C. Reproduced with permission from [115]. Copyright 2008, AIP Publishing LLC.
Figure 20. (a) Cut-off spectra of a SiO1.5 film annealed at 1100 and 1200 °C, measured from the sample edge along the film. The excitation spot was at a distance of several millimeters from the sample edge. The positions of the TE peaks are marked and the other bands have the TM polarization. The TE and TM peaks have polarization parallel and perpendicular to the film surface, respectively. (b) Transmission spectrum of the SiO1.5 film annealed at 1100 °C. Reproduced with permission from [115]. Copyright 2008, AIP Publishing LLC.
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To take the dispersion of the material into account, the transmission spectra can be fitted with a function similar to Equation (3) but containing an additional term describing the wavelength dependence of the spacing δ ν [115]. Equations (1) and (2) are then solved taking the dispersion correction into account. The results show that the dispersion corrections for the refractive index and the film thickness are within experimental errors (Figure 21).
The refractive index and the film thickness can be also calculated using the model of reflection from a multilayer system [153], which does not limit the refractive index (exact equations). The analysis includes both spacing and positions of the cut-off peaks. Equation (3) with an additional term describing the material dispersion is also used in this case [115]. Again, the differences from the simple model are within the experimental errors (“exact” in Figure 21). Using the XPS data for a SiO1.55 film annealed at 1100 °C, it has been concluded that the use of smooth index profile of the refractive index is not crucial to obtain good description of the delocalized cut-off modes. These results suggest that the simple model is sufficient to achieve adequate estimates of the refractive index and film thickness. The m-line measurements lead to the results very similar to those obtained by the PL-filtering effect.
PL-filtering effect has also been interpreted in terms of substrate leaky (or radiation) modes of a planar waveguide [86,87]. In this model, the regular guided modes experience greater loss propagating over a macroscopic distance from the place of creation towards the sample edge. The most likely source of the loss is absorption and scattering by nanocrystals, as well as scattering at the “interface” between the core and cladding layers. In contrast, the beams responsible for generating the substrate modes travel shorter distances through the core region, and the substrate mode undergoes virtually no loss in traveling to the substrate facet. There seems to be no contradiction between the descriptions based on mode delocalization and substrate leaky modes. In particular, both of these models explain the PL-filtering effect based on a smaller absorption in the substrate compared to the film containing Si-nc.
Figure 21. Optical parameters of a SiOx optical wedge (1.5 < x < 1.8) obtained with different models: simple model (solid circles), taking dispersion into account (open circles), and using the exact equations [153] (stars). Reproduced with permission from [115]. Copyright 2008, AIP Publishing LLC.
Figure 21. Optical parameters of a SiOx optical wedge (1.5 < x < 1.8) obtained with different models: simple model (solid circles), taking dispersion into account (open circles), and using the exact equations [153] (stars). Reproduced with permission from [115]. Copyright 2008, AIP Publishing LLC.
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3.4. X-Ray Photoelectron Spectroscopy

XPS measurements provide detailed information about the elemental and chemical composition of the material. Since only a thin layer of the sample (≤10 nm) is investigated with this method, the sample is sputtered with Ar+ ions to obtain information about the bulk material.
In the case of SiOx films, the Si 2p spectrum is fitted by several peaks to obtain the amounts of Si in different oxidation states. Three peaks are often used to describe Si atoms bonded as in crystalline Si (elemental Si), “SiO” (mixture of various suboxides), and SiO2 materials (Figure 22). More complicated fitting with five peaks can be used to obtain the five oxidation states of Si (elemental Si, Si2O, SiO, Si2O3, and SiO2) [154,155,156]. For our samples, the fittings with three and five peaks give similar amounts of elemental Si and SiO2 [116]. Moreover, the use of five fitting curves is problematic for low Si content.
Figure 22. Typical XPS spectrum of a SiOx film fitted with three Gaussians corresponding to Si bonded as in elemental Si, SiO (mixture of suboxides), and SiO2. Figure courtesy of Jouko Lahtinen. Reproduced with permission from [115]. Copyright 2008, AIP Publishing LLC.
Figure 22. Typical XPS spectrum of a SiOx film fitted with three Gaussians corresponding to Si bonded as in elemental Si, SiO (mixture of suboxides), and SiO2. Figure courtesy of Jouko Lahtinen. Reproduced with permission from [115]. Copyright 2008, AIP Publishing LLC.
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3.5. Effective Medium Approximation

The effective medium approximation (Bruggeman theory) connects the effective dielectric constant with the dielectric constants of the three structural components and their volumetric fractions [157]:
a ( ε a ε m ε a + 2 ε m ) + b ( ε b ε m ε b + 2 ε m ) + c ( ε c ε m ε c + 2 ε m ) = 0
where a, b, and c are the volumetric fractions of each component, εa,b,c are the corresponding dielectric constants, and εm is the effective dielectric constant. The effective medium approximation is employed to calculate the complex refractive index n* = n + ik (where k is the extinction coefficient) using the chemical compositions (Si, SiO, and SiO2) obtained from the XPS measurements.

3.6. Temperature Measurements

Laser-induced temperature (T) can be measured in-situ using the intensities of the Stokes (IS) and anti-Stokes (IAS) Raman bands (Figure 23) and the relation:
I AS I S = A e ( E R k T )
where ER is the phonon energy and A is a correction coefficient [95,139]. The coefficient A ~ 0.95 is obtained by measuring the laser-induced temperature of a Si wafer as a function of the laser power and assuming room temperature in the irradiated volume at zero laser power.
Figure 23. Raman spectra of a SiO1.3 film on a silica substrate measured with two laser powers (~30 and ~130 mW focused to a ~40 μm spot). The spectra are vertically shifted and scaled for better presentation.
Figure 23. Raman spectra of a SiO1.3 film on a silica substrate measured with two laser powers (~30 and ~130 mW focused to a ~40 μm spot). The spectra are vertically shifted and scaled for better presentation.
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3.7. Optical Absorption

The film absorption is obtained by measuring transmission and reflection in ultraviolet and visible regions using a broadband light source. The band gap of semiconductors can be obtained from the absorption spectra using the Tauc relation, according to which, the absorption spectrum obeys the following equation [88,158]:
α h ν = A ( h ν E T a u c )
where A is a correction coefficient. Function α h ν is plotted versus h ν and fitted with a straight line. The value of the optical gap (ETauc) is obtained from the intercept of the linear fit with the abscissa.

4. Conclusions

Optical and structural properties of Si-nc in silica films have been described. In order to prepare Si-nc, SiOx (x < 2) films are annealed in a furnace at temperatures up to 1200 °C. For different Si contents, the Si-nc Raman signal and the absorption coefficient are proportional to the amount of elemental Si detected by XPS. On the other hand, the Raman scattering cross-section of elemental Si is about three times smaller than that of crystalline Si. This difference can be explained by the presence of small Si-nc (<2 nm) and/or by the different properties of bulk and nanoscale Si.
The measured optical properties of SiOx films are compared with the values estimated by the effective medium approximation using the XPS results. A good agreement is found between the measured and calculated refractive index. The results for absorption suggest high transparency of nanoscale suboxide in the annealed samples. Thermal annealing increases the degree of Si crystallization; however, the crystallization is not complete after annealing at 1200 °C. The extinction coefficient of elemental Si is found to be between the values of crystalline and amorphous Si.
The PL quantum yield increases as the amount of elemental Si decreases. It follows that the 1.5-eV PL from the SiOx films annealed above 1000 °C is probably not directly from Si-nc responsible for absorption and detected by Raman spectroscopy. According to these results, the light-emitting centers may be small (~1 nm) oxidized Si grains or oxygen-related defects, which are not detectable by Raman spectroscopy. This conclusion is in agreement with the theoretical simulations [114].
The as-prepared SiOx films deposited by MBD and ion implantation are structurally and optically very different. Relatively large amorphous clusters (>2 nm) are present in the MBD films whereas they are absent in the implanted samples as suggested by absorption and Raman spectroscopy. After annealing at ≥1100 °C, these two kinds of samples become similar and possess comparable amounts of Si-nc.
Laser-induced thermal effects are found for SiOx films on silica substrates when illuminated by focused laser light. In our experiments, a temperature of ~350 °C was estimated for SiOx films (x ~ 1.3) on a silica substrate for 488-nm laser intensity of ~104 W cm–2, which decreases the Raman shift by ~6 cm–1. This effect should be taken into account in optical measurements using focused laser beams, especially in Raman microscopy.
CW laser light can produce very high temperatures in free-standing SiOx films and Si/SiO2 SLs, which strongly changes their structure and optical properties. The center of a laser-annealed area is very transparent and presumably consists of amorphous SiO2. Large Si-nc (up to 300 nm) are observed in the ring around the central region. These Si-nc possess high absorption of visible light and they are typically under compressive stress, which is connected with the crystallization from the liquid phase. Some of these large Si-nc exhibit surface features that are formed by eruption of pressurized Si from the film. Some of these “surface” Si-nc are removed from the film leading to holes of similar sizes. The presence of oxygen in the laser-annealing atmosphere decreases the amount of removed Si particles most probably due to oxidation of their surface.
The structure of laser-annealed areas is explained by thermodiffusion in temperature gradient, which means the macroscopic Si–SiO2 phase separation. Comparison of the structure of central regions for laser annealing in oxygen, air, and inert atmospheres excludes the dominating effect of Si oxidation, thus, supporting the mechanism of the macroscopic Si–SiO2 phase separation.
By using a strongly focused laser beam, the structural changes in the free-standing films can be made in areas of submicron sizes. A concept of high-density non-volatile optical memory with superior thermal stability is demonstrated where the information can be read, rewritten and erased by optical means.

Acknowledgments

The authors thank all colleagues who contributed to the results described in this article and whose names appear in the joint publications.

Author Contributions

TN and LK have written this review.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Silicon Nanophotonics: Basic Principles, Present Status and Perspectives; Khriachtchev, L. (Ed.) Pan Stanford: Singapore, Singapore, 2008.
  2. Silicon Photonics II: Components and Integration; Lockwood, D.J.; Pavesi, L. (Eds.) Springer-Verlag: Berlin, Germany, 2011.
  3. Nanostructures in Electronics and Photonics; Rahman, F. (Ed.) Pan Stanford: Singapore, Singapore, 2008.
  4. Yariv, A.; Yeh, P. Photonics: Optical Electronics in Modern Communications; Oxford University Press: Oxford, UK, 2007. [Google Scholar]
  5. Jalali, B.; Fathpour, S. Silicon photonics. J. Lightwave Technol. 2006, 24, 4600–4615. [Google Scholar]
  6. Soref, R. The past, present, and future of silicon photonics. IEEE J. Sel. Top. Quant. Electron. 2006, 12, 1678–1687. [Google Scholar] [CrossRef]
  7. Daldosso, N.; Pavesi, L. Nanosilicon photonics. Laser Photonics Rev. 2009, 3, 508–534. [Google Scholar] [CrossRef]
  8. Silicon Photonics: The State of the Art; Reed, G.T. (Ed.) John Wiley & Sons, Ltd: Chichester, UK, 2008.
  9. Pavesi, L. Will silicon be the photonic material of the third millennium? J. Phys. Cond. Matter 2003, 15, R1169–R1196. [Google Scholar] [CrossRef]
  10. Lockwood, D.J. Light emission in silicon nanostructures. NATO Asi Ser. Ser. E 1998, 348, 185–209. [Google Scholar]
  11. Lockwood, D.J.; Pavesi, L. Silicon fundamentals for photonics applications. Top. Appl. Phys. 2004, 94, 1–50. [Google Scholar]
  12. Delley, B.; Steigmeier, E.F. Quantum confinement in Si nanocrystals. Phys. Rev. B 1993, 47, 1397–1400. [Google Scholar] [CrossRef]
  13. Ogut, S.; Chelikowsky, J.R.; Louie, S.G. Quantum confinement and optical gaps in Si nanocrystals. Phys. Rev. Lett. 1997, 79, 1770–1773. [Google Scholar] [CrossRef]
  14. Balberg, I. Electrical transport mechanisms in three dimensional ensembles of silicon quantum dots. J. App. Phys. 2011, 110, 061301. [Google Scholar] [CrossRef]
  15. Canham, L.T. Silicon quantum wire array fabrication by electrochemical and chemical dissolution of wafers. Appl. Phys. Lett. 1990, 57, 1046–1048. [Google Scholar] [CrossRef]
  16. Cullis, A.G.; Canham, L.T. Visible-light emission due to quantum size effects in highly porous crystalline silicon. Nature 1991, 353, 335–338. [Google Scholar] [CrossRef]
  17. Gardelis, S.; Rimmer, J.S.; Dawson, P.; Hamilton, B.; Kubiak, R.A.; Whall, T.E.; Parker, E.H.C. Evidence for quantum confinement in the photoluminescence of porous Si and SiGe. Appl. Phys. Lett. 1991, 59, 2118–2120. [Google Scholar] [CrossRef]
  18. Bsiesy, A.; Vial, J.C.; Gaspard, F.; Herino, R.; Ligeon, M.; Muller, F.; Romestain, R.; Wasiela, A.; Halimaoui, A.; Bomchil, G. Photoluminescence of high porosity and of electrochemically oxidized porous silicon layers. Surf. Sci. 1991, 254, 195–200. [Google Scholar] [CrossRef]
  19. Delerue, C.; Allan, G.; Lannoo, M. Theoretical aspects of the luminescence of porous silicon. Phys. Rev. B 1993, 48, 11024–11036. [Google Scholar] [CrossRef]
  20. Prokes, S.M. Light emission in thermally oxidized porous silicon: Evidence for oxide-related luminescence. Appl. Phys. Lett. 1993, 62, 3244–3246. [Google Scholar] [CrossRef]
  21. Gole, J.L.; Dudel, F.P.; Grantier, D.; Dixon, D.A. Origin of porous silicon photoluminescence: Evidence for a surface bound oxyhydride-like emitter. Phys. Rev. B 1997, 56, 2137–2153. [Google Scholar] [CrossRef]
  22. Wolkin, M.V.; Jorne, J.; Fauchet, P.M.; Allan, G.; Delerue, C. Electronic states and luminescence in porous silicon quantum dots: The role of oxygen. Phys. Rev. Lett. 1999, 82, 197–200. [Google Scholar] [CrossRef]
  23. Ledoux, G.; Gong, J.; Huisken, F.; Guillois, O.; Reynaud, C. Photoluminescence of size-separated silicon nanocrystals: Confirmation of quantum confinement. Appl. Phys. Lett. 2002, 80, 4834–4836. [Google Scholar] [CrossRef]
  24. Hannah, D.C.; Yang, J.H.; Podsiadlo, P.; Chan, M.K.Y.; Demortiere, A.; Gosztola, D.J.; Prakapenka, V.B.; Schatz, G.C.; Kortshagen, U.; Schaller, R.D. On the origin of photoluminescence in silicon nanocrystals: Pressure-dependent structural and optical studies. Nano Lett. 2012, 12, 4200–4205. [Google Scholar] [CrossRef] [PubMed]
  25. Kim, T.Y.; Park, N.M.; Kim, K.H.; Sung, G.Y.; Ok, Y.W.; Seong, T.Y.; Choi, C.J. Quantum confinement effect of silicon nanocrystals in situ grown in silicon nitride films. Appl. Phys. Lett. 2004, 85, 5355–5357. [Google Scholar] [CrossRef]
  26. Rezgui, B.; Sibai, A.; Nychyporuk, T.; Lemiti, M.; Bremond, G. Photoluminescence and optical absorption properties of silicon quantum dots embedded in Si-rich silicon nitride matrices. J. Lumin. 2009, 129, 1744–1746. [Google Scholar] [CrossRef]
  27. Khriachtchev, L.; Novikov, S.; Lahtinen, J. Thermal annealing of Si/SiO2 materials: Modification of structural and photoluminescence emission properties. J. Appl. Phys. 2002, 92, 5856–5862. [Google Scholar] [CrossRef]
  28. Lu, Z.H.; Lockwood, D.J.; Baribeau, J.M. Quantum confinement and light emission in SiO2/Si superlattices. Nature 1995, 378, 258–260. [Google Scholar] [CrossRef]
  29. Zhuravlev, K.S.; Gilinsky, A.M.; Kobitsky, A.Y. Mechanism of photoluminescence of Si nanocrystals fabricated in a SiO2 matrix. Appl. Phys. Lett. 1998, 73, 2962–2964. [Google Scholar] [CrossRef]
  30. Dhara, S.; Lu, C.Y.; Nair, K.G.M.; Chen, K.H.; Chen, C.P.; Huang, Y.F.; David, C.; Chen, L.C.; Raj, B. Mechanism of bright red emission in Si nanoclusters. Nanotechnology 2008, 19, 395401. [Google Scholar] [CrossRef] [PubMed]
  31. Garrido Fernandez, B.; Lopez, M.; Garcia, C.; Perez-Rodriguez, A.; Morante, J.R.; Bonafos, C.; Carrada, M.; Claverie, A. Influence of average size and interface passivation on the spectral emission of Si nanocrystals embedded in SiO2. J. Appl. Phys. 2002, 91, 798–807. [Google Scholar]
  32. Guha, S. Characterization of Si+ ion-implanted SiO2 films and silica glasses. J. Appl. Phys. 1998, 84, 5210–5217. [Google Scholar] [CrossRef]
  33. Mirabella, S.; Agosta, R.; Franzo, G.; Crupi, I.; Miritello, M.; Lo Savio, R.; Di Stefano, M.A.; Di Marco, S.; Simone, F.; Terrasi, A. Light absorption in silicon quantum dots embedded in silica. J. Appl. Phys. 2009, 106, 103505. [Google Scholar] [CrossRef]
  34. Franzo, G.; Miritello, M.; Boninelli, S.; Lo Savio, R.; Grimaldi, M.G.; Priolo, F.; Iacona, F.; Nicotra, G.; Spinella, C.; Coffa, S. Microstructural evolution of SiOx films and its effect on the luminescence of Si nanoclusters. J. Appl. Phys. 2008, 104, 094306. [Google Scholar] [CrossRef]
  35. Ternon, C.; Dufour, C.; Gourbilleau, F.; Rizk, R. Roles of interfaces in nanostructured silicon luminescence. Eur. Phys. J. B 2004, 41, 325–332. [Google Scholar] [CrossRef]
  36. Alonso, M.I.; Marcus, I.C.; Garriga, M.; Goñi, A.R.; Jedrzejewski, J.; Balberg, I. Evidence of quantum confinement effects on interband optical transitions in Si nanocrystals. Phys. Rev. B 2010, 82, 045302. [Google Scholar] [CrossRef]
  37. Roussel, M.; Talbot, E.; Pareige, P.; Gourbilleau, F. Influence of the supersaturation on Si diffusion and growth of Si nanoparticles in silicon-rich silica. J. Appl. Phys. 2013, 113, 063519. [Google Scholar] [CrossRef]
  38. Antonova, I.V.; Gulyaev, M.; Savir, E.; Jedrzejewski, J.; Balberg, I. Charge storage, photoluminescence, and cluster statistics in ensembles of Si quantum dots. Phys. Rev. B 2008, 77, 125318. [Google Scholar] [CrossRef]
  39. Balberg, I.; Savir, E.; Jedrzejewski, J.; Nassiopoulou, A.G.; Gardelis, S. Fundamental transport processes in ensembles of silicon quantum dots. Phys. Rev. B 2007, 75, 235329. [Google Scholar] [CrossRef]
  40. Iacona, F.; Franzo, G.; Spinella, C. Correlation between luminescence and structural properties of Si nanocrystals. J. Appl. Phys. 2000, 87, 1295–1303. [Google Scholar] [CrossRef]
  41. Trwoga, P.F.; Kenyon, A.J.; Pitt, C.W. Modeling the contribution of quantum confinement to luminescence from silicon nanoclusters. J. Appl. Phys. 1998, 83, 3789–3794. [Google Scholar] [CrossRef]
  42. Boninelli, S.; Iacona, F.; Franzo, G.; Bongiorno, C.; Spinella, C.; Priolo, F. Formation, evolution and photoluminescence properties of Si nanoclusters. J. Phys.: Condens. Matter 2007, 19, 225003. [Google Scholar] [CrossRef]
  43. Nassiopoulou, A.G. Encyclopedia of Nanoscience and Nanotechnology; Nalwa, H.S., Ed.; American Scientific: Valencia, Spain, 2004; Volume 9, pp. 793–813. [Google Scholar]
  44. Gardelis, S.; Nassiopoulou, A.G.; Manousiadis, P.; Milita, S.; Gkanatsiou, A.; Frangis, N.; Lioutas, C.B. Structural and optical characterization of two-dimensional arrays of Si nanocrystals embedded in SiO2 for photovoltaic applications. J. Appl. Phys. 2012, 111, 083536. [Google Scholar] [CrossRef]
  45. Gardelis, S.; Nassiopoulou, A.G.; Vouroutzis, N.; Frangis, N. Effect of exciton migration on the light emission properties in silicon nanocrystal ensembles. J. Appl. Phys. 2009, 105, 113509. [Google Scholar] [CrossRef]
  46. Hiller, D.; Goetze, S.; Munnik, F.; Jivanescu, M.; Gerlach, J.W.; Vogt, J.; Pippel, E.; Zakharov, N.; Stesmans, A.; Zacharias, M. Nitrogen at the Si-nanocrystal/SiO2 interface and its influence on luminescence and interface defects. Phys. Rev. B 2010, 82, 195401. [Google Scholar] [CrossRef]
  47. Seguini, G.; Castro, C.; Schamm-Chardon, S.; BenAssayag, G.; Pellegrino, P.; Perego, M. Scaling size of the interplay between quantum confinement and surface related effects in nanostructured silicon. Appl. Phys. Lett. 2013, 103, 023103. [Google Scholar] [CrossRef]
  48. Khriachtchev, L.; Räsänen, M.; Novikov, S.; Pavesi, L. Systematic correlation between Raman spectra, photoluminescence intensity, and absorption coefficient of silica layers containing Si nanocrystals. Appl. Phys. Lett. 2004, 85, 1511–1513. [Google Scholar] [CrossRef]
  49. Khriachtchev, L.; Räsänen, M.; Novikov, S.; Lahtinen, J. Tunable wavelength-selective waveguiding of photoluminescence in Si-rich silica optical wedges. J. Appl. Phys. 2004, 95, 7592–7601. [Google Scholar] [CrossRef]
  50. Zacharias, M.; Blasing, J.; Veit, P.; Tsybeskov, L.; Hirschman, K.; Fauchet, P.M. Thermal crystallization of amorphous Si/SiO2 superlattices. Appl. Phys. Lett. 1999, 74, 2614–2616. [Google Scholar] [CrossRef]
  51. Zacharias, M.; Heitmann, J.; Scholz, R.; Kahler, U.; Schmidt, M.; Blasing, J. Size-controlled highly luminescent silicon nanocrystals: A SiO/SiO2 superlattice approach. Appl. Phys. Lett. 2002, 80, 661–663. [Google Scholar] [CrossRef]
  52. Godefroo, S.; Hayne, M.; Jivanescu, M.; Stesmans, A.; Zacharias, M.; Lebedev, O.I.; van Tendeloo, G.; Moshchalkov, V.V. Classification and control of the origin of photoluminescence from Si nanocrystals. Nat. Nanotechnol. 2008, 3, 174–178. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  53. Hiller, D.; Jivanescu, M.; Stesmans, A.; Zacharias, M. P-b(0) centers at the Si-nanocrystal/SiO2 interface as the dominant photoluminescence quenching defect. J. Appl. Phys. 2010, 107, 084309. [Google Scholar] [CrossRef]
  54. Novikov, S.V.; Sinkkonen, J.; Kilpela, O.; Gastev, S.V. Visible light emission from MBD-grown Si/SiO2 superlattices. J. Cryst. Growth 1997, 175, 514–518. [Google Scholar] [CrossRef]
  55. Khriachtchev, L.; Räsänen, M.; Novikov, S.; Kilpela, O.; Sinkkonen, J. Raman scattering from very thin Si layers of Si/SiO2 superlattices: Experimental evidence of structural modification in the 0.8-3.5 nm thickness region. J. Appl. Phys. 1999, 86, 5601–5608. [Google Scholar] [CrossRef]
  56. Khriachtchev, L.; Räsänen, M.; Novikov, S. Laser-controlled stress of Si nanocrystals in a free-standing Si/SiO2 superlattice. Appl. Phys. Lett. 2006, 88, 013102. [Google Scholar] [CrossRef]
  57. Khriachtchev, L.; Novikov, S.; Lahtinen, J.; Räsänen, M. Wavelength-selective optical waveguiding of photoluminescence in a thermally annealed Si/SiO2 superlattice. J. Phys.: Condens. Matter 2004, 16, 3219–3228. [Google Scholar] [CrossRef]
  58. Pavesi, L.; Dal Negro, L.; Mazzoleni, C.; Franzo, G.; Priolo, F. Optical gain in silicon nanocrystals. Nature 2000, 408, 440–444. [Google Scholar] [CrossRef]
  59. Khriachtchev, L.; Räsänen, M.; Novikov, S.; Sinkkonen, J. Optical gain in Si/SiO2 lattice: Experimental evidence with nanosecond pulses. Appl. Phys. Lett. 2001, 79, 1249–1251. [Google Scholar] [CrossRef]
  60. Koshida, N.; Koyama, H. Visible electroluminescence from porous silicon. Appl. Phys. Lett. 1992, 60, 347–349. [Google Scholar] [CrossRef]
  61. Franzo, G.; Irrera, A.; Moreira, E.C.; Miritello, M.; Iacona, F.; Sanfilippo, D.; Di Stefano, G.; Fallica, P.G.; Priolo, F. Electroluminescence of silicon nanocrystals in MOS structures. Appl. Phys. A 2002, 74, 1–5. [Google Scholar] [CrossRef]
  62. Zhou, F.L.; Head, J.D. Role of Si=O in the photoluminescence of porous silicon. J. Phys. Chem. B 2000, 104, 9981–9986. [Google Scholar] [CrossRef]
  63. Takeoka, S.; Fujii, M.; Hayashi, S. Size-dependent photoluminescence from surface-oxidized Si nanocrystals in a weak confinement regime. Phys. Rev. B 2000, 62, 16820–16825. [Google Scholar] [CrossRef]
  64. Nesheva, D.; Raptis, C.; Perakis, A.; Bineva, I.; Aneva, Z.; Levi, Z.; Alexandrova, S.; Hofmeister, H. Raman scattering and photoluminescence from Si nanoparticles in annealed SiOx thin films. J. Appl. Phys. 2002, 92, 4678–4683. [Google Scholar] [CrossRef]
  65. Lioudakis, E.; Othonos, A.; Hadjisavvas, G.C.; Kelires, P.C.; Nassiopoulou, A.G. Quantum confinement and interface structure of Si nanocrystals of sizes 3–5 nm embedded in a-SiO2. Phys. E 2007, 38, 128–134. [Google Scholar] [CrossRef]
  66. Garcia, C.; Garrido, B.; Pellegrino, P.; Ferre, R.; Moreno, J.A.; Morante, J.R.; Pavesi, L.; Cazzanelli, M. Size dependence of lifetime and absorption cross section of Si nanocrystals embedded in SiO2. Appl. Phys. Lett. 2003, 82, 1595–1597. [Google Scholar] [CrossRef]
  67. Kanemitsu, Y.; Ogawa, T.; Shiraishi, K.; Takeda, K. Visible photoluminescence from oxidized Si nanometer-sized spheres: Exciton confinement on a spherical shell. Phys. Rev. B 1993, 48, 4883–4886. [Google Scholar] [CrossRef]
  68. Kanemitsu, Y.; Uto, H.; Masumoto, Y.; Matsumoto, T.; Futagi, T.; Mimura, H. Microstructure and optical properties of free-standing porous silicon films: Size dependence of absorption spectra in Si nanometer-sized srystallites. Phys. Rev. B 1993, 48, 2827–2830. [Google Scholar] [CrossRef]
  69. Garoufalis, C.S.; Zdetsis, A.D. High accuracy calculations of the optical gap and absorption spectrum of oxygen contaminated Si nanocrystals. Phys. Chem. Chem. Phys. 2006, 8, 808–813. [Google Scholar] [CrossRef] [PubMed]
  70. Dohnalova, K.; Kusova, K.; Pelant, I. Time-resolved photoluminescence spectroscopy of the initial oxidation stage of small silicon nanocrystals. Appl. Phys. Lett. 2009, 94, 211903. [Google Scholar] [CrossRef]
  71. Averboukh, B.; Huber, R.; Cheah, K.W.; Shen, Y.R.; Qin, G.G.; Ma, Z.C.; Zong, W.H. Luminescence studies of a Si/SiO2 superlattice. J. Appl. Phys. 2002, 92, 3564–3568. [Google Scholar] [CrossRef]
  72. Iacona, F.; Bongiorno, C.; Spinella, C.; Boninelli, S.; Priolo, F. Formation and evolution of luminescent Si nanoclusters produced by thermal annealing of SiOx films. J. Appl. Phys. 2004, 95, 3723–3732. [Google Scholar] [CrossRef]
  73. Wang, Y.Q.; Smirani, R.; Ross, G.G. The formation mechanism of Si nanocrystals in SiO2. J. Cryst. Growth 2006, 294, 486–489. [Google Scholar] [CrossRef]
  74. Naciri, A.E.; Mansour, M.; Johann, L.; Grob, J.J.; Eckert, C. Optical study of Si nanocrystals in Si/SiO2 layers by spectroscopic ellipsometry. Nucl. Instrum. Meth. B 2004, 216, 167–172. [Google Scholar] [CrossRef]
  75. Falcony, C.; Calleja, W.; Aceves, M.; Siqueiros, J.M.; Machorro, R.; CotaAraiza, L.; Soto, G.; Farias, M.H. Characterization of excess Si in nonstoichiometric SiO2 films by optical and surface analysis techniques. J. Electrochem. Soc. 1997, 144, 379–383. [Google Scholar] [CrossRef]
  76. Charvet, S.; Madelon, R.; Gourbilleau, F.; Rizk, R. Ellipsometric spectroscopy study of photoluminescent Si/SiO2 systems obtained by magnetron co-sputtering. J. Lumin. 1998, 80, 257–261. [Google Scholar] [CrossRef]
  77. Daldosso, N.; Melchiorri, M.; Pavesi, L.; Pucker, G.; Gourbilleau, F.; Chausserie, S.; Belarouci, A.; Portier, X.; Dufour, C. Optical losses and absorption cross-section of silicon nanocrystals. J. Lumin. 2006, 121, 344–348. [Google Scholar] [CrossRef]
  78. Navarro-Urrios, D.; Riboli, F.; Cazzanelli, M.; Chiasera, A.; Daldosso, N.; Pavesi, L.; Oton, C.J.; Heitmann, J.; Yi, L.X.; Scholz, R.; et al. Birefringence characterization of mono-dispersed silicon nanocrystals planar waveguides. Opt. Mater. 2005, 27, 763–768. [Google Scholar] [CrossRef]
  79. Khriachtchev, L.; Navarro-Urrios, D.; Pavesi, L.; Oton, C.J.; Capuj, N.E.; Novikov, S. Spectroscopy of silica layers containing Si nanocrystals: Experimental evidence of optical birefringence. J. Appl. Phys. 2007, 101, 044310. [Google Scholar] [CrossRef]
  80. Moreno, J.A.; Garrido, B.; Pellegrino, P.; Garcia, C.; Arbiol, J.; Morante, J.R.; Marie, P.; Gourbilleau, F.; Rizk, R. Size dependence of refractive index of Si nanoclusters embedded in SiO2. J. Appl. Phys. 2005, 98, 013523. [Google Scholar] [CrossRef]
  81. Chen, T.P.; Liu, Y.; Tse, M.S.; Fung, S.; Dong, G. Profile of optical constants of SiO2 thin films containing Si nanocrystals. J. Appl. Phys. 2004, 95, 8481–8483. [Google Scholar] [CrossRef] [Green Version]
  82. Amans, D.; Callard, S.; Gagnaire, A.; Joseph, J.; Ledoux, G.; Huisken, F. Ellipsometric study of silicon nanocrystal optical constants. J. Appl. Phys. 2003, 93, 4173–4179. [Google Scholar] [CrossRef]
  83. Mishra, P.; Jain, K.P. Raman, photoluminescence and optical absorption studies on nanocrystalline silicon. Mat. Sci. Eng. B 2002, 95, 202–213. [Google Scholar] [CrossRef]
  84. von Behren, J.; van Buuren, T.; Zacharias, M.; Chimowitz, E.H.; Fauchet, P.M. Quantum confinement in nanoscale silicon: The correlation of size with bandgap and luminescence. Solid State Commun. 1998, 105, 317–322. [Google Scholar]
  85. Khriachtchev, L.; Räsänen, M.; Novikov, S. Efficient wavelength-selective optical waveguiding in a silica layer containing Si nanocrystals. Appl. Phys. Lett. 2003, 83, 3018–3020. [Google Scholar] [CrossRef]
  86. Valenta, J.; Ostatnicky, T.; Pelant, I.; Elliman, R.G.; Linnros, J.; Honerlage, B. Microcavity-like leaky mode emission from a planar optical waveguide made of luminescent silicon nanocrystals. J. Appl. Phys. 2004, 96, 5222–5225. [Google Scholar] [CrossRef]
  87. Pelant, I.; Ostatnicky, T.; Valenta, J.; Luterova, K.; Skopalova, E.; Mates, T.; Elliman, R.G. Waveguide cores containing silicon nanocrystals as active spectral filters for silicon-based photonics. Appl. Phys. B 2006, 83, 87–91. [Google Scholar] [CrossRef]
  88. Tauc, J.; Grigorov, R.; Vancu, A. Optical properties and electronic structure of amorphous germanium. Phys. Status Solidi B 1966, 15, 627–637. [Google Scholar] [CrossRef]
  89. BenChorin, M.; Averboukh, B.; Kovalev, D.; Polisski, G.; Koch, F. Influence of quantum confinement on the critical points of the band structure of Si. Phys. Rev. Lett. 1996, 77, 763–766. [Google Scholar] [CrossRef]
  90. Podhorodecki, A.; Zatryb, G.; Misiewicz, J.; Wojcik, J.; Mascher, P. Influence of the annealing temperature and silicon concentration on the absorption and emission properties of Si nanocrystals. J. Appl. Phys. 2007, 102, 043104. [Google Scholar] [CrossRef]
  91. Inokuma, T.; Wakayama, Y.; Muramoto, T.; Aoki, R.; Kurata, Y.; Hasegawa, S. Optical properties of Si clusters and Si nanocrystallites in high-temperature annealed SiOx films. J. Appl. Phys. 1998, 83, 2228–2234. [Google Scholar] [CrossRef]
  92. Thompson, M.O.; Galvin, G.J.; Mayer, J.W.; Peercy, P.S.; Poate, J.M.; Jacobson, D.C.; Cullis, A.G.; Chew, N.G. Melting temperature and explosive crystallization of amorphous silicon during pulsed laser irradiation. Phys. Rev. Lett. 1984, 52, 2360–2363. [Google Scholar] [CrossRef]
  93. Koyama, H.; Fauchet, P.M. Laser-induced thermal effects on the optical properties of free-standing porous silicon films. J. Appl. Phys. 2000, 87, 1788–1794. [Google Scholar] [CrossRef]
  94. Khriachtchev, L.; Räsänen, M.; Novikov, S. Free-standing silica film containing Si nanocrystals: Photoluminescence, Raman scattering, optical waveguiding, and laser-induced thermal effects. Appl. Phys. Lett. 2005, 86, 141911. [Google Scholar] [CrossRef]
  95. Khriachtchev, L.; Räsänen, M.; Novikov, S. Continuous-wave laser annealing of free-standing Si/SiO2 superlattice: Modification of optical, structural, and light-emitting properties. J. Appl. Phys. 2006, 100, 053502. [Google Scholar] [CrossRef]
  96. Khriachtchev, L.; Novikov, S. Laser-induced thermal effects on Si/SiO2 free-standing superlattices. Appl. Phys. A 2007, 87, 761–766. [Google Scholar] [CrossRef]
  97. Koyama, H.; Fauchet, P.M. Very large continuous-wave-laser-induced optical absorption in porous silicon films: Evidence for thermal effects. Appl. Phys. Lett. 1998, 73, 3259–3261. [Google Scholar] [CrossRef]
  98. Mchedlidze, T.; Arguirov, T.; Kouteva-Arguirova, S.; Kittler, M. Light induced solid-phase crystallization of Si nanolayers in Si/SiO2 multiple quantum wells. J. Appl. Phys. 2010, 107, 124302. [Google Scholar] [CrossRef]
  99. Khriachtchev, L.; Ossicini, S.; Iacona, F.; Gourbilleau, F. Silicon nanoscale materials: From theoretical simulations to photonic applications. Int. J. Photoenergy 2012, 2012, 872576. [Google Scholar]
  100. Daldosso, N.; Luppi, M.; Ossicini, S.; Degoli, E.; Magri, R.; Dalba, G.; Fornasini, P.; Grisenti, R.; Rocca, F.; Pavesi, L.; et al. Role of the interface region on the optoelectronic properties of silicon nanocrystals embedded in SiO2. Phys. Rev. B 2003, 68, 085327. [Google Scholar] [CrossRef]
  101. Djurabekova, F.; Nordlund, K. Atomistic simulation of the interface structure of Si nanocrystals embedded in amorphous silica. Phys. Rev. B 2008, 77, 115325. [Google Scholar] [CrossRef]
  102. Luppi, M.; Ossicini, S. Multiple SiO bonds at the silicon cluster surface. J. Appl. Phys. 2003, 94, 2130–2132. [Google Scholar] [CrossRef]
  103. Vasiliev, I.; Chelikowsky, J.R.; Martin, R.M. Surface oxidation effects on the optical properties of silicon nanocrystals. Phys. Rev. B 2002, 65, 121302. [Google Scholar] [CrossRef]
  104. Puzder, A.; Williamson, A.J.; Grossman, J.C.; Galli, G. Computational studies of the optical emission of silicon nanocrystals. J. Am. Chem. Soc 2003, 125, 2786–2791. [Google Scholar] [CrossRef] [PubMed]
  105. Pennycook, T.J.; Hadjisavvas, G.; Idrobo, J.C.; Kelires, P.C.; Pantelides, S.T. Optical gaps of free and embedded Si nanoclusters: Density functional theory calculations. Phys. Rev. B 2010, 82, 125310. [Google Scholar] [CrossRef]
  106. Luppi, E.; Iori, F.; Magri, R.; Pulci, O.; Ossicini, S.; Degoli, E.; Olevano, V. Excitons in silicon nanocrystallites: The nature of luminescence. Phys. Rev. B 2007, 75, 033303. [Google Scholar] [CrossRef]
  107. Kleovoulou, K.; Kelires, P.C. Stress state of embedded Si nanocrystals. Phys. Rev. B 2013, 88, 085424. [Google Scholar] [CrossRef]
  108. Hadjisavvas, G.; Kelires, P.C. Structure and energetics of Si nanocrystals embedded in a-SiO2. Phys. Rev. Lett. 2004, 93, 226104. [Google Scholar] [CrossRef] [PubMed]
  109. Kleovoulou, K.; Kelires, P.C. Local rigidity and physical trends in embedded Si nanocrystals. Phys. Rev. B 2013, 88, 245202. [Google Scholar] [CrossRef]
  110. Guerra, R.; Degoli, E.; Ossicini, S. Size, oxidation, and strain in small Si/SiO2 nanocrystals. Phys. Rev. B 2009, 80, 155332. [Google Scholar] [CrossRef]
  111. Watanabe, T.; Tatsumura, K.; Ohdomari, I. SiO2/Si interface structure and its formation studied by large-scale molecular dynamics simulation. Appl. Surf. Sci. 2004, 237, 125–133. [Google Scholar] [CrossRef]
  112. Guerra, R.; Marri, I.; Magri, R.; Martin-Samos, L.; Pulci, O.; Degoli, E.; Ossicini, S. Silicon nanocrystallites in a SiO2 matrix: Role of disorder and size. Phys. Rev. B 2009, 79, 155320. [Google Scholar] [CrossRef]
  113. Guerra, R.; Marri, I.; Magri, R.; Martin-Samos, L.; Pulci, O.; Degoli, E.; Ossicini, S. Optical properties of silicon nanocrystallites in SiO2 matrix: Crystalline vs. amorphous case. Superlattices Microstruct. 2009, 46, 246–253. [Google Scholar] [CrossRef]
  114. Guerra, R.; Ossicini, S. High luminescence in small SiO/SiO2 nanocrystals: A theoretical study. Phys. Rev. B 2010, 81, 245307. [Google Scholar] [CrossRef]
  115. Khriachtchev, L.; Nikitin, T.; Oton, C.J.; Velagapudi, R.; Sainio, J.; Lahtinen, J.; Novikov, S. Optical properties of silicon nanocrystals in silica: Results from spectral filtering effect, m-line technique, and X-ray photoelectron spectroscopy. J. Appl. Phys. 2008, 104, 104316. [Google Scholar] [CrossRef]
  116. Nikitin, T.; Velagapudi, R.; Sainio, J.; Lahtinen, J.; Räsänen, M.; Novikov, S.; Khriachtchev, L. Optical and structural properties of SiOx films grown by molecular beam deposition: Effect of the Si concentration and annealing temperature. J. Appl. Phys. 2012, 112, 094316. [Google Scholar] [CrossRef]
  117. Khriachtchev, L.; Nikitin, T.; Velagapudi, R.; Lahtinen, J.; Novikov, S. Light-emission mechanism of thermally annealed silicon-rich silicon oxide revisited: What is the role of silicon nanocrystals? Appl. Phys. Lett. 2009, 94, 043115. [Google Scholar] [CrossRef]
  118. Nikitin, T.; Aitola, K.; Novikov, S.; Räsänen, M.; Velagapudi, R.; Sainio, J.; Lahtinen, J.; Mizohata, K.; Ahlgren, T.; Khriachtchev, L. Optical and structural properties of silicon-rich silicon oxide films: Comparison of ion implantation and molecular beam deposition methods. Phys. Status Solidi A 2011, 208, 2176–2181. [Google Scholar] [CrossRef]
  119. Hartstein, A.; Tsang, J.C.; Dimaria, D.J.; Dong, D.W. Observation of amorphous silicon regions in silicon-rich silicon dioxide films. Appl. Phys. Lett. 1980, 36, 836–837. [Google Scholar] [CrossRef]
  120. Khriachtchev, L.; Kilpela, O.; Karirinne, S.; Keranen, J.; Lepisto, T. Substrate-dependent crystallization and enhancement of visible photoluminescence in thermal annealing of Si/SiO2 superlattices. Appl. Phys. Lett. 2001, 78, 323–325. [Google Scholar] [CrossRef]
  121. Faraci, G.; Gibilisco, S.; Russo, P.; Pennisi, A.R.; La Rosa, S. Modified Raman confinement model for Si nanocrystals. Phys. Rev. B 2006, 73, 033307. [Google Scholar] [CrossRef]
  122. Campbell, I.H.; Fauchet, P.M. The effects of microcrystal size and shape on the one phonon Raman spectra of crystalline semiconductors. Solid State Commun. 1986, 58, 739–741. [Google Scholar] [CrossRef]
  123. Khriachtchev, L.; Novikov, S.; Kilpela, O. Optics of Si/SiO2 superlattices: Application to Raman scattering and photoluminescence measurements. J. Appl. Phys. 2000, 87, 7805–7813. [Google Scholar] [CrossRef]
  124. Seino, K.; Bechstedt, F.; Kroll, P. Influence of SiO2 matrix on electronic and optical properties of Si nanocrystals. Nanotechnology 2009, 20, 135702. [Google Scholar] [CrossRef] [PubMed]
  125. Novikov, S.; Sinkkonen, J.; Nikitin, T.; Khriachtchev, L.; Räsänen, M.; Haimi, E. Free-standing SiO2 films containing Si nanocrystals directly suitable for transmission electron microscopy. Microelectron. J. 2008, 39, 518–522. [Google Scholar] [CrossRef]
  126. Kogelnik, H.; Ramaswamy, V. Scaling rules for thin-film optical waveguides. Appl. Opt. 1974, 13, 1857–1862. [Google Scholar] [CrossRef] [PubMed]
  127. Unger, H.G. Planar Optical Waveguides and Fibres; Oxford University Press: Oxford, UK, 1977. [Google Scholar]
  128. Yurtsever, A.; Weyland, M.; Muller, D.A. Three-dimensional imaging of nonspherical silicon nanoparticles embedded in silicon oxide by plasmon tomography. Appl. Phys. Lett. 2006, 89, 151920. [Google Scholar] [CrossRef]
  129. Zatryb, G.; Podhorodecki, A.; Misiewicz, J.; Cardin, J.; Gourbilleau, F. Correlation between matrix structural order and compressive stress exerted on silicon nanocrystals embedded in silicon-rich silicon oxide. Nanoscale Res. Lett. 2013, 8, 40. [Google Scholar] [CrossRef] [PubMed]
  130. Munekuni, S.; Yamanaka, T.; Shimogaichi, Y.; Tohmon, R.; Ohki, Y.; Nagasawa, K.; Hama, Y. Various types of nonbridging oxygen hole center in highpurity silica glass. J. Appl. Phys. 1990, 68, 1212–1217. [Google Scholar] [CrossRef]
  131. Glinka, Y.D.; Lin, S.H.; Hwang, L.P.; Chen, Y.T. Photoluminescence from mesoporous silica: Similarity of properties to porous silicon. Appl. Phys. Lett. 2000, 77, 3968–3970. [Google Scholar] [CrossRef]
  132. Borsella, E.; D'Amato, R.; Fabbri, F.; Falconieri, M.; Trave, E.; Bello, V.; Mattei, G.; Nie, Y.R.; Wang, D.Y. On the role of non-bridging oxygen centers in the red luminescence emission from silicon nanocrystals. Phys. Status Solidi C 2011, 8, 974–978. [Google Scholar] [CrossRef]
  133. Koponen, L.; Tunturivuori, L.O.; Puska, M.J.; Nieminen, R.M. Effect of the surrounding oxide on the photoabsorption spectra of Si nanocrystals. Phys. Rev. B 2009, 79, 235332. [Google Scholar] [CrossRef]
  134. Garcia, C.; Garrido, B.; Pellegrino, P.; Ferre, R.; Moreno, J.A.; Pavesi, L.; Cazzanelli, M.; Morante, J.R. Absorption cross-sections and lifetimes as a function of size in Si nanocrystals embedded in SiO2. Phys. E 2003, 16, 429–433. [Google Scholar] [CrossRef]
  135. Shimizu-Iwayama, T.; Kurumado, N.; Hole, D.E.; Townsend, P.D. Optical properties of silicon nanoclusters fabricated by ion implantation. J. Appl. Phys. 1998, 83, 6018–6022. [Google Scholar] [CrossRef]
  136. Lee, B.G.; Hiller, D.; Luo, J.W.; Semonin, O.E.; Beard, M.C.; Zacharias, M.; Stradins, P. Strained interface defects in silicon nanocrystals. Adv. Funct. Mater. 2012, 22, 3223–3232. [Google Scholar] [CrossRef]
  137. Kusova, K.; Ondic, L.; Klimesova, E.; Herynkova, K.; Pelant, I.; Danis, S.; Valenta, J.; Gallart, M.; Ziegler, M.; Honerlage, B.; et al. Luminescence of free-standing versus matrix-embedded oxide-passivated silicon nanocrystals: The role of matrix-induced strain. Appl. Phys. Lett. 2012, 101, 143101. [Google Scholar] [CrossRef]
  138. Faraci, G.; Gibilisco, S.; Pennisi, A.R. Quantum confinement and thermal effects on the Raman spectra of Si nanocrystals. Phys. Rev. B 2009, 80, 193410. [Google Scholar] [CrossRef]
  139. Balkanski, M.; Wallis, R.F.; Haro, E. Anharmonic effects in light scattering due to optical phonons in silicon. Phys. Rev. B 1983, 28, 1928–1934. [Google Scholar] [CrossRef]
  140. Khriachtchev, L.; Nikitin, T.; Räsänen, M.; Domanskaya, A.; Boninelli, S.; Iacona, F.; Engdahl, A.; Juhanoja, J.; Novikov, S. Continuous-wave laser annealing of Si-rich oxide: A microscopic picture of macroscopic Si-SiO2 phase separation. J. Appl. Phys. 2010, 108, 124301. [Google Scholar] [CrossRef]
  141. Nikitin, T.; Kemell, M.; Puukilainen, E.; Boninelli, S.; Iacona, F.; Räsänen, M.; Ritala, M.; Novikov, S.; Khriachtchev, L. Surface fingerprints of individual silicon nanocrystals in laser-annealed Si/SiO2 superlattice: Evidence of nanoeruptions of laser-pressurized silicon. J. Appl. Phys. 2012, 111, 124302. [Google Scholar] [CrossRef]
  142. Nikitin, T.; Kemell, M.; Puukilainen, E.; Räsänen, M.; Ritala, M.; Novikov, S.; Khriachtchev, L. Continuous-wave laser annealing of a Si/SiO2 superlattice: Effect of the ambient atmosphere and exposure period. Sci. Adv. Mater. 2014, 6, 1000–1010. [Google Scholar] [CrossRef]
  143. Bachels, T.; Schafer, R. Binding energies of neutral silicon clusters. Chem. Phys. Lett. 2000, 324, 365–372. [Google Scholar] [CrossRef]
  144. Murphy, D.V.; Brueck, S.R.J. Enhanced raman-scattering from silicon microstructures. Opt. Lett. 1983, 8, 494–496. [Google Scholar] [CrossRef] [PubMed]
  145. Doremus, R.H. Viscosity of silica. J. Appl. Phys. 2002, 92, 7619–7629. [Google Scholar] [CrossRef]
  146. Wada, K.; Suzuki, A.; Sato, H.; Kikuchi, R. Soret effect in solids. J. Phys. Chem. Solids 1985, 46, 1195–1205. [Google Scholar] [CrossRef]
  147. Zhang, K.J.; Briggs, M.E.; Gammon, R.W.; Sengers, J.V. Optical measurement of the Soret coefficient and the diffusion coefficient of liquid mixtures. J. Chem. Phys. 1996, 104, 6881–6892. [Google Scholar] [CrossRef]
  148. Susa, M.; Nagata, K. Thermal oxidation of silicon substrates through oxygen diffusion. Mat. Sci. Eng. A 1991, 146, 51–62. [Google Scholar] [CrossRef]
  149. Deal, B.E.; Grove, A.S. General relationship for thermal oxidation of silicon. J. App. Phys. 1965, 36, 3770–3778. [Google Scholar] [CrossRef]
  150. Lukes, F.; Schmidt, E. Oxidation of silicon in dry oxygen. J. Phys. Chem. Solids 1965, 26, 1353–1357. [Google Scholar] [CrossRef]
  151. Nikitin, T.; Khriachtchev, L.; Räsänen, M.; Novikov, S. Optical memory of silicon nanocrystals with submicron spatial resolution and very high thermal stability. Appl. Phys. Lett. 2009, 94, 173116. [Google Scholar] [CrossRef]
  152. Khriachtchev, L. Comment on Optical absorption measurements of silica containing Si nanocrystals produced by ion implantation and thermal annealing. Appl. Phys. Lett. 2002, 81, 1357–1358. [Google Scholar] [CrossRef]
  153. Oton, C.J.; Ghulinyan, M.; Gaburro, Z.; Bettotti, P.; Pavesi, L.; Pancheri, L.; Gialanella, S.; Capuj, N.E. Scattering rings as a tool for birefringence measurements in porous silicon. J. Appl. Phys. 2003, 94, 6334–6340. [Google Scholar] [CrossRef]
  154. Renault, O.; Marlier, R.; Gely, M.; De Salvo, B.; Baron, T.; Hansson, M.; Barrett, N.T. Synchrotron radiation X-ray photoelectron spectroscopy of Si nanocrystals grown onto Al2O3/Si surfaces. Appl. Phys. Lett. 2005, 87, 163119. [Google Scholar] [CrossRef]
  155. Kim, S.; Kim, M.C.; Choi, S.H.; Kim, K.J.; Hwang, H.N.; Hwang, C.C. Size dependence of Si 2p core-level shift at Si nanocrystal/SiO2 interfaces. Appl. Phys. Lett. 2007, 91, 103113. [Google Scholar] [CrossRef]
  156. Barbagiovanni, E.G.; Goncharova, L.V.; Simpson, P.J. Electronic structure study of ion-implanted Si quantum dots in a SiO2 matrix: Analysis of quantum confinement theories. Phys. Rev. B 2011, 83, 035112. [Google Scholar] [CrossRef]
  157. Bruggeman, D.A.G. Berechnung verschiedener physikalischer Konstanten von heterogenen Substanzen. I. Dielektrizitätskonstanten und Leitfähigkeiten der Mischkörper aus isotropen Substanzen. Ann. Phys. 1935, 416, 636–664. [Google Scholar] [CrossRef]
  158. Knief, S.; von Niessen, W. Disorder, defects, and optical absorption in a-Si and a-Si:H. Phys. Rev. B 1999, 59, 12940–12946. [Google Scholar] [CrossRef]

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Nikitin, T.; Khriachtchev, L. Optical and Structural Properties of Si Nanocrystals in SiO2 Films. Nanomaterials 2015, 5, 614-655. https://doi.org/10.3390/nano5020614

AMA Style

Nikitin T, Khriachtchev L. Optical and Structural Properties of Si Nanocrystals in SiO2 Films. Nanomaterials. 2015; 5(2):614-655. https://doi.org/10.3390/nano5020614

Chicago/Turabian Style

Nikitin, Timur, and Leonid Khriachtchev. 2015. "Optical and Structural Properties of Si Nanocrystals in SiO2 Films" Nanomaterials 5, no. 2: 614-655. https://doi.org/10.3390/nano5020614

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