Document Type : Research Paper
Authors
Department of physics, College of Education for pure sciences, University of Babylon, Iraq
Abstract
Keywords
INTRODUCTION
Nanotechnology is an emerging technology. This new generation is significantly influencing the global economy through the creation of innovative and high-volume items, product utilisation, and more effective production techniques. Nanotechnology produces several forms of nanoparticles, including metal, metal oxide, doped, and undoped metal and metal oxide. Nanoparticles are substances that have a size ranging from 1 to 100 nanometers in at least one dimension. Within that limited scope, materials exhibit singular mechanical, chemical, and physical characteristics [1]. Polymer nanocomposites have become famous because of their ability to attain unique characteristics [2]. Metal and semiconductor nanoparticles have exceptional optical and electrical characteristics, and polymers are considered suitable host materials for them [3]. Nanocomposites in the (inorganic/organic) system have gained technological strength in the fields of linear and nonlinear optics and solar cells due to their unique properties and innovative methods [4]. Polymers possess qualities similar to inorganic materials but offer advantages such as flexibility, processability, corrosion resistance, affordability, and lightweight nature. Inorganic materials possess beneficial characteristics including temperature stability and superior mechanical strength. Polymer-inorganic hybrids are being used in a variety of applications such as solar cell batteries, sensors, and television sets[5].
Polymethyl methacrylate (PMMA) is one of the oldest and most well-known polymers, with the chemical formula (C5H8O2)n. PMMA is naturally transparent and colourless, with a density ranging from 1.15 to 1.19 g/cm3. It is a polymer. PMMA is a highly durable thermoplastic that has garnered significant attention as a polymer waveguide for optical components and optoelectronic devices. This is due to its outstanding characteristics, such as superior mechanical properties, high scratch resistance, suitability for electrical engineering applications because of its excellent dielectric properties, and thermal stability owing to its resistance to temperature fluctuations [6, 7].
The II-VI semiconductor zinc selenide (ZnSe) shows great promise. It features a large direct band gap of 2.7 eV, a high visual transmittance, a high refractive index, and a high exciton binding energy. ZnSe’s unusual properties make it suitable for a variety of applications, including thin-film solar cells, blue-light generating diodes, gas sensors, and photocatalysts [8].
Scientists are interested in silicon nanoparticles (Si NPs) because of their distinctive optoelectronic capabilities and stable, varied chemistry [9]. Silicon nanoparticles offer benefits such as abundant availability and non-toxicity to living organisms [10]. Highly sought-after in the technology industry are ultra-fine silicon nanoparticles with diameters smaller than 10 nm. They are suitable for utilisation in microelectronic devices, solar energy conversion, LEDs, tunable lasers, and sensors [11,12]. Ultra-fine silicon nanoparticles show potential as anode materials for lithium-ion batteries [13].
You can get silicon nanoparticles in a number of different ways. Physical procedures alone are represented here, and they include things like ball milling, thermal degradation, and pulsed laser ablation [14]. There are physio-chemical treatments that could work, such as chemical methods and the widely used electrochemical etching process. Particle size reduction, size uniformity, efficient scalability, and fine-grained control over surface chemistry are common outcomes of these approaches [15]. The semiconductor silicon is found in the periodic table’s group IVA. Its atomic weight is 28.086 and its atomic number is 14. With a lattice parameter of 0.543 nm, silicon exhibits a diamond cubic crystal structure. In contrast to other semiconductors, silicon has an indirect bandgap and its optical and electrical properties change dramatically when it gets close to the 4 nm bulk Bohr radius [16].
This study aims to create PMMA/ZnSe/Si nanocomposites and analyse their optical properties for potential use in several optical fields such as photodetection.
MATERIALS AND METHODS
The (PMMA/ZnSe/Si) nanocomposites were prepared by dissolving 1gm of PMMA in 50 mL of Chloroform at 70°C for 30 minutes with constant stirring using a magnetic stirrer to ensure a uniform solution. Zinc selenide (ZnSe) and silicon (Si) nanoparticles were incorporated into polymethyl methacrylate (PMMA) at different weight ratios of 1%, 3%, 5%, and 7%. An Olympus optical microscope model named Top View, specifically the Nikon 73346 type, equipped with an automated camera and set to a 10x magnification, was used to analyse the surface of the films. The optical properties of nanocomposites (PMMA/ZnSe/Si) were analysed with a UV-1800 0A-Shimadzu spectrophotometer.
You are provided with the absorption coefficient (α) as [17]:
The optical absorbance is represented by A, and t is the sample thickness. The indirect optical energy gap is calculated as [18]:
To determine the indirect transition between allowed and forbidden states, where B is a constant, hυ is the photon energy, Eg is the energy gap, and m = 2 and 3, respectively. That which is known as the refractive index (n) is [19]
To find the extinction coefficient (k), where R is the reflection, one uses [20]
Where λ is wavelength. The real (ε1) and imaginary (ε2) dielectric constants are: [21]
Equation (op) defines the optical conductivity. [22]
Where c stands for the speed of light.
RESULTS AND DISCUSSION
The XRD patterns were used to determine the crystallographic structure of PMMA polymer and its nanocomposite films. The nanocomposites had varying ratios (1, 3, 5 and 7 wt.%) of ZnSe and Si NPs. The purpose of this analysis was to identify the structure of the polymer nanocomposites at room temperature, as depicted in Fig. 1. The figure shows that the PMMA displays broad diffraction peaks at 2θ = 15.39° (strong) and 30.29°, which indicate its amorphous nature [13]. The figure demonstrates that PMMA/ZnSe/Si nanocomposites, containing a small amount of ZnSe and Si NPs, exhibited weak and wide-ranging peaks, similar to pure PMMA. This suggests that there are no chemical bonds formed between PMMA and ZnSe and Si NPs. The nanocomposites with high ZnSe and Si NPs loading (7 wt.%) showed pronounced XRD peaks at 27.12o, 45.39o and 53.69o corresponding to the miller indices of (111), (220) and (311) which confirms that ZnSe NPs has cubic phase with prominent peak at (111) [JCPDS card no. 37-1463 [24], while the peaks at 28.54o, 47.54o, 56.29o, 66.09o and 72.89o corresponding to the miller indices of (111), (220), (311), (103) and (112) which confirms that Si NPs has hexagonal structure [powder diffraction file: 25-1133] [25]. From these patterns of the nanocomposites, it is realized that ZnSe and Si NPs loading (7 wt.%) affected the structural characteristics of PMMA which is due to the fact that ZnSe and Si NPs was mixed chemically and change the amorphas nature for the pure PMMA to the polycrystalline.
The placement of ZnSe and Si NPs within the PMMA polymer is analyzed using a field emission scanning electron microscope (FESEM), and the influence of these particles on the nanocomposites is then verified. Films produced from (PMMA/ZnSe/Si) nanocomposites with varied ZnSe and Si nanoparticle concentrations are depicted in Fig. 2. It is clear from image (a) that the polymer is cohesive and homogenous, and that adding more ZnSe and Si NPs to PMMA polymer changes the surface structure of the system (see images b, c, d and e). at low loading for the ZnSe and Si NPs, the distributed homogenous inside the polymer matrix while, at high concentration (7 wt.%) for the ZnSe and Si NPs, these particles are aggregate to form clusters that may be due to the interacted between the ZnSe and Si NPs with PMMA polymer matrix that confirmed with XRD. This outcome aligns with the findings of researchers [26, 27].
The optical microscope (OM) shows PMMA/ZnSe/Si nanocomposites’ surface morphological variations. Fig. 3 shows a 10x optical microscope of (PMMA/ZnSe/Si) nanocomposites. A show a homogeneous phase without phase separation. Fig. 1 (B-E) shows ZnSe and Si NPs dispersed uniformly on the PMMA polymer film. Lower concentrations cause ZnSe and Si NPs to cluster. Increased ZnSe and Si NP concentrations in PMMA polymer generate a route network. These routes allow charge carriers to flow, changing material properties. This method was suitable for nanocomposite film production. The behavior matches [28].
Fig. 4 shows how (PMMA/ZnSe/Si) nanocomposites absorbance and wavelength correlate. The strong ultraviolet absorption in all samples is due to photons’ large energy, which interacts with atoms and excites electrons from lower to higher energy states. The nanocomposite’s near-infrared absorption is low because incident photons have limited energy levels and cannot interact with its atoms. The film absorption phenomenon is stronger at shorter wavelengths and decreases with wavelength. Absorption is positively correlated with ZnSe and Si NP concentrations. Additionally, charge carriers rise. The energy level density from impurity atoms in the conduction and valence bands explains the observed behaviours. The outcome matches [29, 30]
Fig. 5 shows the transmittance spectra of PMMA/ZnSe/Si films as a function of incident light wavelength. Spectrum displayed for different ZnSe and Si nanoparticle concentrations. As shown in the graph, ZnSe and Si concentrations decrease transmittance. The phenomena are caused by ZnSe and Si electrons in their valence shells absorbing light’s electromagnetic energy and transitioning to higher energy states. Because moving electrons occupy energy locations in each band, the material can absorb incoming light and prevent transmission [31].
Nanocomposites of (PMMA/ZnSe/Si) are compared with respect to their photon energy absorption coefficient in Fig. 6. Higher wavelengths and lower energies cause a noticeable drop in absorption coefficients. It is highly unlikely that electrons will be displaced from low energy photons (hv<Egoρ) [32]. This investigation reveals the effect of the absorbance coefficient on electron transition. At high energies, the absorption coefficient is expected to exceed 104 cm-1. This points to photon and electron conservation of energy and momentum during direct electron transitions. In contrast, the absorption coefficient of 104 cm-1 at low energies suggests that phonons enhance electric momentum in indirect transitions [33]. Nanocomposites comprising PMMA, ZnSe, and Si have an absorbance coefficient below 104 cm-1. An indirect electron transition is suggested by this and other findings.
A medium’s extinction coefficient measures an electromagnetic wave’s intensity reduction. Fig. 7 shows the wavelength-extinction coefficient relationship. The figure shows a positive link between ZnSe and Si nanoparticle concentrations and extinction coefficients. The energy gap impurities provide a density of levels that increase film absorbance [34].
The correlation between wavelength and refractive index is illustrated in Fig. 8. Nanoparticles of PMMA, ZnSe, and Si have a positive correlation with the refractive index. Doping agents boost energy levels by increasing the amount by which incident rays are inverted. The result is an increase in the refractive index due to the stronger reflected light. The high refractive index is a result of the poor UV transmittance (T). The reference states that the high transmittance (T) causes the visible and near-infrared (IR) regions to have low refractive index values. The density of nanocomposites is increased when the concentrations of ZnSe and Si rise via the n-values [35].
The energy gaps for allowed and disallowed indirect transitions are shown in Figs. 9 and 10. To get the energy gap, draw a straight line from the curve’s peak to the x-axis at (αhv) 1/2 = 0. Conversely, the forbidden energy gap is identified when (αhv)1/3 = 0. ZnSe and Si nanoparticle concentrations decrease energy gap values. Doping creates energy gap levels, causing this drop. Electrons move from the valence band to the energy gap local levels and then to the conduction band [36].
A material’s polarization response to electromagnetic radiation can be measured by its dielectric constant. The real dielectric constant (ε1) and the imaginary dielectric constant (ε2) are the usual components that define this phenomenon. The changes in the real and imaginary dielectric constants with wavelength for PMMA/ZnSe/Si nanocomposites are shown in Figs. 11 and 12, respectively. Both the real and imaginary dielectric constants were positively correlated with the ZnSe/Si nanoparticle ratio in the investigation. This phenomenon could be explained by the fact that nanoparticles enhance electric polarization. The dielectric constant is raised by an increase in electric polarization because dipole concentration is increased. Fig. 8 shows the real dielectric constant curves, which are closely connected to the refractive index curves and behave similarly. One possible explanation for the observed resemblance is because the extinction coefficient (k) has a far smaller effect on the real dielectric constant than the refractive index (n), especially when squared. Fig. 11 displays the graph of the imaginary dielectric constant with respect to wavelength. At both visible and infrared wavelengths, the damping coefficient influences the imaginary part of the dielectric constant. In the ranges described before, the refractive index remains constant, whereas the extinction coefficients increase as the wavelength increases, as stated in [37].
The optical conductivity of PMMA/ZnSe/Si nanocomposites is shown in Fig. 13. All nanocomposite specimens show a drop in optical conductivity as wavelength increases, followed by an increase at lower wavelengths. All nanocomposite materials absorb more photons in this spectral range, which increases optical conductivity at lower photon wavelengths. Charge transfer excitations rise as a result. The spectral data shows strong visible and near-infrared light transmission. Also, optical conductivity increases proportionally with ZnSe and Si nanoparticle concentration. This phenomenon is caused by localized energy levels in the energy gap [38].
CONCLUSION
The films of (PMMA/ZnSe/Si) nanocomposites were created in the present work using the casting approach. From the XRD, it found the nature amorphas for the PMMA and with additive high loading (7 wt.%) for the ZnSe and Si NPs, the nature amorphas for the PMMA convert to the polycrystalline. The Field Emission Scanning Electron Microscopy (FESEM) analysis showed that the ZnSe and Si nanoparticles were uniformly distributed throughout the PMMA matrix polymers. As the nanoparticle concentration increased, the optical microscope images revealed the formation of charge carrier network pathways inside the polymeric matrix. An increase in UV absorbance is one of the optical features of (PMMA/ZnSe/Si) nanocomposites. Based on these results, the nanocomposites may have a future in optoelectronics. Optical properties of nanocomposites, including extinction coefficient, real and imaginary dielectric constant, optical conductivity, absorbance, absorption coefficient, refractive index, and concentrations of ZnSe and Si nanoparticles, are enhanced with increasing nanoparticle concentrations. Conversely, when the nanoparticle concentration in these nanocomposites increases, their transmittance drops. The optical energy gap for permitted indirect transitions comes down from 4.4 eV to 3.2 eV and for banned indirect transitions from 4.3 eV to 3.1 eV at a concentration of 4 wt.%. Several industries that deal with optoelectronic devices stand to gain a great deal from the narrowing of the energy band gap.
CONFLICT OF INTEREST
The authors declare that there are no conflicts of interest regarding this article.