Introduction

The unique controlled morphology and wide optical emission properties of low-dimensional (in particular 0D and 1D) semiconductors make them one of the most sophisticated core technologies in optoelectronics1, photonics2,3, and plasmonics4,5. In particular, the significance of fullerenes6 has inspired much systematic curiosity in many artificial periodic patterns such as strings of beads7, chains8, and bamboo-like tubes9 in nanostructures. These morphological peculiarities were accomplished by the following specific synthetic manipulations: metal particle migration induced by annealing7, stress induced by new carbon layer formation10, the periodic instability of catalyst particles11,12, and metal atom evaporation8. Most of these structures have been confined to carbon-based materials. The special case of spiral twisted morphologies as a patterning series has been considered a hot topic due to the unique design and physical/chemical identification compared with those of the other forms. Thus, many promising approaches for the synthesis of twisted materials have been studied for various potential applications such as liquid crystals, sensors, and optical activity13,14,15,16,17,18. However, despite the striking progress in twisted structures, most synthetic routes are limited to chemical-based reactions that include polymers, closely akin to self-assembly19,20. The development of physical procedures for the desired twisted morphology remains a challenge. To date, optical research on the luminescent efficiency of Si based not on amorphous nanoclusters (a-Si NCs) but on crystalline nanoclusters (c-Si NCs)21 has been carried out on the following: the formation of porous silicon22; implantation of Si+ ions23; laser ablation24; sputtering of Si25, SiO26, and SiO225; and structural evolution via thermal annealing27. In most cases, however, the main luminescent techniques of Si-based materials have been focused on the production of Si nanocrystals or transformation from amorphous to crystalline structures. Therefore, innovative new methods dissimilar to conventional methods are required to highly enhance the optical efficiency and range of Si-based materials.

In this paper, we present a solution to the above problems, namely, well-designed twisted micro-/nanotube morphology via a physical reaction basis and a luminescent origin through the embedment of metal instead of c-Si NCs. Our synthetic route, which we call direct substrate growth (DSG), is novel in that it is a one-step process that requires no direct source, catalyst, and post-treatment. In addition, it has the advantages of size-controllable one-dimensional (1D) tube formation and emission spectra throughout the visible range at the same time. Our original concept is that the main factors that influence the final morphological and optical properties depend mostly on the selections of the pre-contaminated concentration and embedded nanoparticle size.

Results

In this study, tubular flower-like SiOx embedded with Sn nanoparticles (~5 nm in size) was synthesized for the first time by using a Si substrate with assistance from In2O3 and graphite powders in pre-deposited SnO2 thin films. Figure 1 presents the main concept with an image of a real gerbera flower: (a) the basic concept of a hollow structure, (b) the flower-like morphology, and (c) the connected loops of the inner part of the petal. The detailed preparation procedure is described in Materials and Methods. An experimental study expressed the carboreduction related to SnO2 dissociation within the SnO2/C/Sn system as follows28:

Figure 1
figure 1

Real flower (gerbera) and corresponding SEM and TEM images: (a) SEM image showing a hollow SiOx structure with overlapping scale-like patterns on the surface, (b) SEM image of a typical flower-like SiOx, and (c) TEM image of flattened loops similar to the petals of flower-like SiOx.

Based on the Si–Sn phase diagram29 (Supplementary Fig. S1), when the Sn nanoparticles are stuck in a Si substrate, the Sn circumference is encircled by neighboring Si atoms. At a glance, it seems that mass (Si) diffusion from the underlying substrate through the metal particles can reasonably explain the nucleation and growth mechanism30,31 because there is no other Si source except the substrate in this system. However, only diffusion of Si atoms is not sufficient to attain the supersaturation for Si nucleation at the contact points between Sn-edge and Si-surface in that a range of surface melting for Si substrate is too narrow (a few tens of degrees) to drastically lower the melting point of Si and to effectively induce Si diffusion. Accordingly, both nucleation and growth of SiOx structures would be dominated by volatile SiO vapor generation from the Si substrate, especially at lower O2 pressures and higher temperatures (620–1000 °C)32,33 in agreement with our synthetic conditions (remnant O2 and 1100 °C). The vapor-phased SiO directly adsorbs onto the surface of Si-Sn or Si-O-Sn structures. The liquidized small-size ternary droplets, reacting with the surface of Si compared with bulk Si, facilitate more rapid nuclei formation, and hence continuous growth development34. In addition, SnO and Sn are mixed with In2O3, and the Sn4+ ions originating from the pre-contaminated SnO2 thick films are distributed on In3+ sites to facilitate the substitution of Sn4+ for In3+35. The additional effects of the roles of In2O3 powder and carrier gas are presented in Supplementary Fig. S2.

Figure 2 shows SEM images characterizing the process of the twisted growth mechanism for tubular flower-like SiOx. As shown by the schematic in Fig. 2a, Si atoms obtained from the Si substrate and the remaining O gas combine with Sn atoms originating from nanoparticles or the internal SnO2 film to form ternary (Si–O–Sn) droplets. However, based on the phase diagram (Supplementary Fig. S1), the ternary solid solution cannot include a Sn concentration higher than 0.1 at%, which suggests that the elemental composition of a droplet is mostly a mixture of Si and O. Supplementary Figure S3 confirms the existence of three main elemental compositions at the (a) tube and (b) tip regions. The low level of Sn incorporation into a ternary droplet results in a uniform dose distribution for the whole SiOx tube. The initial interfacial reaction-controlled process at the smooth surface and the diffusion-controlled reaction at the rough surface occur consecutively. Once the SiOx nanostructures nucleate at the ternary interface, the dominant individual SiOx particles (e.g., ranging from 3.6 to 4.6 μm in Fig. 2b) start to grow. They keep the hollow SiOx shape (i.e., no center SiOx) with the overall diameter mostly the same as (or smaller than) the Sn nanoparticle size (e.g., 2.2 μm in Fig. 2c). If a SiOx tube is forced to realize a minimum diameter, it would likely follow a spiral configuration for an adjustable fit to make the smallest cylindrical volume (Fig. 2a). In other words, the natural tendency to suppress the total surface energy may maximize the bonding interaction, suggesting the formation of twisted surface morphology among numerous SiOx loops grown from the circumference of the droplet (Fig. 2d). In particular, the torsion image in Fig. 2e may be used as clear evidence of our conjecture. Namely, the main reason for the helical surface pattern on tubular SiOx seems to be connected with behavior to minimize the surface energy because our samples cannot be satisfactorily explained by other reasons such as crystallization36,37 and alignment38 owing to the instant effect. Figure 2f,g show the crystallized Sn-embedded amorphous SiOx. The influx of Sn nanoparticles is made possible through the diffusion of ternary droplets or dissociation of the SnO2 film. The Supplementary real-time Movie S1 supports the explanation of Sn embedment above. The Sn nanocrystallites are randomly distributed into the amorphous SiOx (Fig. 2f), which implies no clear fringe, and produces the constant spacing in Fig. 2g. The interplanar spacing of Sn monocrystalline is 0.279 nm, which matches the (101) lattice plane of tetragonal Sn well (JCPDS 04-0673, lattice parameters: a = 0.5831 nm and c = 0.3182 (S.G I41/amd (141)) (Fig. 2g).

Figure 2
figure 2

Schematic sequence of the formation of tubular 1D SiOx and characteristic SEM and TEM images: (a) adsorption-nucleation-twisted growth procedure with a pre-contaminated SnO2 film in the tube furnace, (b) typical Sn particles (exact Si–Sn–O droplet on the Si surface), (c) cross-section of a SiOx tube comprising SiOx fragments, (d) typical SiOx tube morphology, (e) a cut TEM image indicating the twisted SiOx, (f) enlarged Sn-embedded SiOx, and (g) an HRTEM image of crystalline Sn embedded in amorphous SiOx.

When the respective SiOx loops intersect with one another (Supplementary Fig. S4), the SiOx generation series occurs in sequence to keep the front ellipse-shaped Sn head (Supplementary Fig. S4a). Occasionally, if two Sn heads are combined together, new SiOx tubes grow, showing two SiOx parts (Supplementary Fig. S4b). Then, the left- and right-handed directions are not particularly important. The SEM image in Supplementary Fig. S4b indicates that the large-sized Sn lump at the tip may act as a nucleation site for branched nanowires, just like Sn embedment into the SiOx described above. In the case of balloon whisk-like SiOx formation (Fig. 3a and Supplementary Fig. S4c), more than two SiOx loops meet to combine at the tip. Sometimes, the Sn lump size is too large to lead to axial growth. Therefore, the extra thermal and pressured energy and source (SiOx) normally used for the SiOx tube growth mechanism, are consumed by SiOx nanowires diverging longitudinally or transversely between the Sn tip and SiOx tube for some distance (Fig. 3b–d). This indirectly implies that many SiOx loops are involved in SiOx tube formation. Particularly, compared with the general twisted growth of SiOx (Fig. 2e), these loops arising from balloon whisk-like SiOx have no torsion and twist shape (Fig. 3e) owing to running out of surplus energy to split all loops. Figure 3f,g show enlarged TEM and HRTEM images, respectively, of the swollen unit SiOx loop. Many different lattice planes such as (110) and (200) were found, which confirms that Sn nanoparticles are crystalline. After the flat flower-like formation of SiOx, the morphological transition accumulates regular patterns on the tube surface, as shown in Supplementary Fig. S5.

Figure 3
figure 3

Schematic of the morphological transition from balloon whisk-like SiOx to flat continuous aggregated loops and electron microscopic images of balloon whisk-like SiOx: (a) steps of morphological change arising from excess thermal and partial pressure, (b) typical flower-like SiOx formation originating from the transition in (a,c) various balloon whisk-like SiOx morphologies, (d) an enlarged image of the head part, (e) an enlarged image of loops in balloon whisk-like morphologies, (f) an enlarged image of the loop, and (g) an HRTEM image of (f).

When the flower-like SiOx is completely spread out, new and thinner SiOx nanowires are created at both the center and edges (Fig. 4a–c): the center site is around the Sn lump (Fig. 4d–f), and the edge site is near the pre-formed outside SiOx (Fig. 4g–i). In the first stage of nucleation and growth at the surface of the Sn lump, SiOx can grow via combination effects mixing the solution–liquid–solid (SLS)39,40 and vapor–liquid–solid (VLS)41,42 mechanisms. The VLS mechanism somewhat differs from the SLS process in how the chemical source is introduced in the chamber. The former is carried out through the flow of gas, whereas the latter is performed via one-off means in a product39, even though the basic principles of using molten metal particles are similar. Based on our experimental procedure, a large number of Sn metals not only permeate into the ternary droplets centered on the Sn lump as a type of SLS growth but also adsorb onto the surface of the ternary droplets as a kind of VLS growth. On the other hand, the outside SiOx wall also acts as a nucleation site at the same time as the Sn lump. Contrary to the evidence of nucleation and growth on the Sn lump surface, only the SLS growth system predominates instead of the VLS process because there are no remarkable tips in the newly produced shorter and thinner SiOx nanowires. As described above, when all of the Sn-centered tips of the twisted SiOx nanotubes encounter each other at one point, the twisted behavior is stopped and fixed. Therefore, extra energy is used to separate or expand the individual SiOx loops. Both the number and split degree of loops increasingly become more severe to make an almost flat plane, even though there is some space in reality (left schematic illustration in Fig. 4j). The individual loops may combine into the whole SiOx material without any disconnection to produce a closed system. Additional SiOx nanowires may grow from both sides of the Sn lump and pre-formed SiOx wall in this closed system. At this point of time, another possible point should be considered. If any defects including 0D, 1D, and 2D flaws occur on the preformed SiOx walls (right schematic illustration in Fig. 4j), a large internal pressure produced by evaporation of the Sn lump would move from the larger partial pressure region (around the unflawed Sn part) towards the smaller partial pressure region (around flawed SiOx part) to cause crystalline Sn (200)-embedded nanowires (Fig. 4k,l). The cross-sectional image in Fig. 4f indicates that sharp cutting planes come not from the pattern grown from the Sn lump but from a strong internal force. Here, the different lengths of SiOx depend on how much new SiOx nanowires are influenced by the internal vapor pressure of the Sn lump in the closed system according to the boundary condition, volume size, process duration, and kind of defects. The specific microstructural and compositional data for the behavior and arrangement/elemental composition of newly produced SiOx nanowires in flower-like SiOx sections are given in Supplementary Figs S6–8.

Figure 4
figure 4

Schematic illustration and TEM images corresponding to individual regions in flower-like SiOx: (a) schematic illustration of SiOx growths on both sides, (b) cross-sectional TEM image of flower-like SiOx, (c) enlarged loop part obtained from (b,d) nucleation and growth at Sn lump region, (e) boundary image of (d,f) cut SiOx image originating from partial pressure differences, (g) nucleation and growth at the SiOx wall region, (h) boundary image of (g,i) typical nano-SiOx, (j) Sn partial pressure in the closed loops, (k) Sn-embedded SiOx nanowire remaining in the closed loops, and (l) an HRTEM of (k).

Figure 5 displays the normalized PL spectra of as-synthesized tubular SiOx with embedded Sn (~5 nm) at room temperature. For the enlarged PL spectra, Fig. 5a shows a relatively narrow emission band centered at ~397 nm in the violet region corresponding to a Gaussian fitting consisting of violet emissions (376 and 398 nm) and blue emissions (423 and 455 nm). Figure 5b of the same samples reveals a relatively broad emission band centered around 540 nm in the yellow region corresponding to minor violet (382 nm), green (526 nm), and orange (631 nm) emissions of the Gaussian fitting. The other PL result is in Supplementary Fig. S9. No considerable PL emission peak in the SiOx structure can be observed in the visible region (350–700 nm) apart from special functionalized Si quantum effects such as the strain43, Si nanoporous pillar array (Si-NPA)44, and molecular beam epitaxy (MBE)45. Thus, the specific violet and yellow emissions from tubular SiOx in this work cannot be fully accounted for by SiOx micro- and nano-tubes themselves because our samples consist of an amorphous structure, as shown in Figs 2 and 3. They may be caused by the embedment of Sn nanoparticles (~5 nm), which is known as quantum confinement effect (i.e., quantum dot)46,47. The energy band gap may be opened and tailored even in zero-gap materials analogous to graphene by confinement effects48,49. However, it is difficult to obtain a precise variability in the PL emission spectra over the samples because very precise control of the size and shape of Sn quantum dots in SiOx is almost impossible. It is clear that the tolerance of various sized and shaped Sn quantum dots (i.e., less than 10 nm) to preserve the visible-range PL emission spectra is somewhat broad, as shown in Figs 2f,3f,4k and 5c,d. In other words, the wavelength and intensity of PL emissions obtained from different parts of samples depend very sensitively on the sizes and shapes of Sn quantum dots even though all our samples have broadly similar tendencies in the range of 380–400 nm and 530–540 nm. Consequently, the PL properties tend to depend on the PL sample collecting location in Sn-embedded SiOx structures synthesized under the same process condition. Apart from the quantum confinement effect, the controlled hybridization of crystalline and amorphous structures would be another factor to enhance the PL properties. Li et al.50 reported that the PL emission of crystalline Sn and amorphous SnO2 nanoparticles reveals ultraviolet and blue emission due to the synergistic effect of the quantum size and interfacial electronic-coupling between the crystalline core (Sn) and amorphous shell (SnO2). The fact that the major emission range of Sn-embedded SiOx tubes stretches from the longer wavelength (red emission) region to the shorter wavelength (violet emission) region, irrespective of the location of the sample (e.g., Z-stack at the tube (Fig. 5c) and confocal spectral imaging at the flower (Fig. 5d)), shows that there is a strong dependence on the size and shape of the Sn nanoparticles. The information on the subsidiary movie (Supplementary Movie S2, 3) offers further support for the continuous emissive transition of products at the tube and flower. Despite the remarkable strides in new synthetic techniques presented in this work, a complete understanding is still lacking. The effect on many process variables remains to be verified, such as the quantity of pre-contaminated SnO2 and supporting materials, synthesis temperature, process pressure, and duration.

Figure 5: Optical properties of SiOx nanotubes.
figure 5

PL spectra of as-synthesized Sn-embedded SiOx tubes with Gaussian fit (a) at 397 nm and (b) at 540 nm. (c) Z-stack alongside the axial direction at the SiOx tube region. (d) Confocal spectral image from 417 nm to 748 nm at the SiOx flower region.

Discussion

The somewhat modified VLS technique surrounded with SnO2 films is fairly uncomplicated but very powerful for fabricating metal embedded tubular SiOx by using the DSG without multiple artificial manipulations. The results indicate not only unique morphologies (twisted-, balloon whisk-like, and flower-like SiOx) but also optical properties throughout the visible range based on the combination of Sn heads and control of Sn particle sizes and shapes. The morphological transition is based on the pre-contaminated concentration, while the wide-ranging emissions originate from quantum confinement effect. This synthetic procedure is of tremendous interest for all kinds of innovative and progressive applications in nanoscience and nanotechnology.

Methods

The fundamental synthetic steps for SiOx tubes follow the typical vapor–liquid–solid (VLS) mechanism51,52. The only exceptional difference between our technique and the traditional method is whether or not the pre-contaminated metal oxide thick film is present before the production of target SiOx tubes from p-type Si (100) substrates. Preformed SnO2 thick films may be able to provide the embedment of minute Sn nanoparticles into SiOx tubes due to the carbothermal reductive dissociation of SnO2 for SnO and Sn over 1050 °C28. In our previous paper, we presented the growth factor and process variables for SnO2 film, as no specific substrate, onto the surface of alumina tubes53. The same procedure was repeated up to 10 times to supply the satisfactory amount Sn nanoparticles. After SnO2 formation to an adequate thickness, thermal evaporation was carried out with a mixture of In2O3 (1 g) and graphite (0.1 g) powders in the alumina boat by putting a Si (100) substrate upside down on the ceramic boat. Both In2O3 and graphite acted as supporting materials for the substitution for Sn and creation of CO/CO2 gases, respectively. The detailed process variables are as follows: The process temperature was fixed to 1100 °C for 40 min. An inlet gas of Ar (200 standard cubic centimeters per minute (sccm)) without any additional reacting gas was introduced into the chamber to make the total pressure in the tube 0.1 Torr (1 Torr = 1.333 × 102 Pa). To compare the effects of the supporting materials (In2O3 and graphite) and used gas (Ar), the same cycles were reproduced with two different types: no In2O3 and graphite powders (a) with Ar gas (b) without Ar gas. Finally, when the furnace temperature was cooled to room temperature (RT), white-like SiOx products were collected.

A field emission scanning electron microscope (FESEM, Hitachi S-4200, 20 kV) was used to characterize the surface morphology of SiOx tubes, and a field emission transmission electron microscope (FETEM, JEOL JEM-2100F, 200 kV) was used to observe the local microstructures inside and outside the samples. High-resolution TEM (HRTEM) measurements were performed at confined areas in the thin products (70 nm) pre-cut via the ultramicrotomb (MTX/RMC) after the scratched samples were embedded and trimmed in the capsule with epofix (EMS). The emissive origin of Sn-embedded tubular SiOx was analyzed according to the photoluminescence (PL, Maple) by using a He–Cd laser (325 nm, 55 MW) and confocal laser scanning microscopy (CLSM, LSM 510 META) with a diode-laser (405 nm, 30 mW) at RT. For the individual longitudinal and spectral properties, both Z-stacks generated by incrementally stepping and spectral imaging from 417 nm to 748 nm by META detector techniques were executed.

Additional Information

How to cite this article: Jin, C. et al. Growth Mechanism and Luminescent Properties of Amorphous SiOx Structures via Phase Equilibrium in Binary System. Sci. Rep. 6, 30901; doi: 10.1038/srep30901 (2016).