Cadmium Oxide Research Articles

Investigating the Electrical, Power Factor, and Figure of Merit Characteristics of Cadmium Oxide Nanostructures Fabricated via Thermal Evaporation in Vacuum

A cadmium dioxide nanostructure was fabricated on silicon and quartz substrates through oblique angle deposition (OAD). The synthesis involved the initial thermal evaporation of high-purity cadmium metal films at varying deposition angles on the substrates, followed by a 1.5-hour oxidation process at 773 K in a conventional furnace to produce cadmium oxide nanostructures. X-ray diffraction (XRD) analysis revealed the development of crystalline structures within the cadmium oxide (CdO) films. The deposition angle exhibited a significant impact, influencing the preferred orientation along the (111) planes more substantially than the normal incident angle. I-V measurements and assessments of electrical conductivity were conducted under both light and dark conditions for the CdO films. The photocurrent generated in an oblique (Al/CdO/p-Si/Al) heterojunction exceeded that of a standard detector under illumination. The investigation explored the thermoelectric properties of CdO nanomaterials, including the figure of merit (M), power factor (P.F.), and Seebeck coefficient (S), for both normally deposited and obliquely deposited films. The results demonstrated an enhancement in the figure of merit with oblique deposition, potentially attributed to increased roughness, resulting in reduced thermal conductivity and an elevated figure of merit. All findings indicated superior performance for deposition angles (θº = 50º & 70º) in comparison to normal deposition (θº = 0º).

A novel approach to assessing cardiotoxic effects of nanoparticles in a toxicological experiment

Introduction. The study of nanoparticles for potential cardiotoxic effects is a comprehensive multi-stage process based on an integrated approach. Along with generally accepted research methods, molecular biology techniques using modern highly sensitive equipment are being actively introduced into toxicology testing. The aim of the study was to describe a novel approach to assessing cardiotoxic effects of nanoparticles, from the molecular level to the functional response of the whole organism. Materials and methods. Our new approach to assessing cardiotoxic effects of nanoparticles in rats included the examination of changes at the molecular (e.g., the ratio of myosin heavy chains), subcellular (by electron microscopy), cellular and tissue (by histological testing), system and organ (by non-invasive recording of electrocardiogram and blood pressure parameters and biochemical testing of blood serum) levels. We have tested the proposed approach by evaluating lead (PBO) and cadmium oxide (CdO) nanoparticles in rats. Results. Hypotension observed after PbO and/or CdO nanoparticle exposure indicates to the damage to the vascular bed due to penetration and accumulation of the nanoparticles in vascular cells, as well as direct damage to the endothelium, increased oxidative stress, and inflammation. In accordance with the system for assessing nanoparticle-induced cardiotoxicity developed on the basis of toxicology test results, lead and cadmium oxides, both separately and combined, have a pronounced cardiotoxic effect. Limitations. Our work was limited to examining the main indicators of the cardiotoxic effects of nanoparticles in a toxicological experiment on one animal species (rats). Conclusion. The data analysis revealed varying degrees of manifestation of nanoparticle cardiotoxicity, both at the molecular level and at the intracellular, cellular, tissue, organ, and body levels. The use of this approach will allow a better in-depth assessing effects of nano-sized particles on the heart and blood vessels for identification of risks for cardiovascular disease.

Optical properties of CdO thin films

Cadmium Oxide thin films were deposited on glass substrate by spray pyrolysis technique at different temperatures (300,350,400, 500)oC. The optical properties of the films were studied in this work. The optical band-gap was determined from absorption spectra, it was found that the optical band-gap was within the range of (2.5-2.56)eV also width of localized states and another optical properties.

CdO Nanoparticles by chemical method as antimicrobial therapy in order to maintain of healthy cells

Abstract A simple chemical method that has the potential for large-scale manufacturing was used to produce Cadmium Oxide (CdO) Nanoparticles (NPs). Using X-ray diffraction (XRD), atomic force microscopy (AFM), Fourier transform infrared (FTIR), and ultraviolet-visible (UV-vis) spectroscopy, The optical and Structural properties of synthesized CdO were investigated, strong antibacterial activity of CdO nanoparticles is demonstrated against a variety of Gram-positive, Gram-negative, and fungal diseases. Therefore, CdO NPs might be a potential substitute to develop as an antibacterial agent against bacterial strains that are resistant to many drugs. Applications of CdO NPs might provide important discoveries in a variety of domains, including antibacterial systems and medical devices.

Analysis and Characterization of Cadmium Oxide Nanoparticle Films for Optical Properties

Analysis and Characterization of Cadmium Oxide Nanoparticle Films for Optical Properties

Structure-optical properties of CdO glass matrix with low levels of cobalt impurities

The impacted role of cadmium oxide (CdO) on the structure-optical properties of current borate glasses with low cobalt oxide impurities was studied. The study was performed on a glass system of the formula [x CdO – (80-x) B2O3 – 0.4 CoO – 19.6 Na2O]; x = 0, 6, 12, 18 and 24 mol%, and produced by melt quenching method. Structure and optical absorption spectroscopy were done to explore the electronic transitions of Co cations inside the glass matrix. The obtained data indicated that structure and optical properties were significantly changed following CdO additives. Bands of optical absorption within both visible and near-infrared ranges showed signatures from Co2+ cations in the tetrahedral and octahedral sites, while Co3+ cations in the octahedral sites within the glass network. Optical absorption also changed significantly for the CdO-doped glasses which exhibited red shifts in visible absorption bands and blue shifts in the NIR absorption bands. The obtained absorption bands in both visible and NIR were employed to obtain the crystal field splitting parameter (Δt) showing augmented records from 3364 cm−1 to 3377 cm−1 with more CdO addition. The Tauc gap energy values were then attained showing decreased values from 3.50 to 3.27 eV when further CdO is added. Further, the impacted role of CdO addition on the nonlinearity optical properties of the present glasses was finally estimated. Potential increases in the linear and nonlinear optical are discussed based on polarizability and basicity increments inside the glass matrix.

Citrus limon peel-based biosynthesis: Lead oxide, zinc oxide, cadmium oxide, and copper oxide nano quantum dots for subtraction of anionic Actas Pink dye (AAPD)

ABSTRACT Adsorption is a highly effective method for wastewater quality adjustment, offering advantages such as low cost and availability of adsorbents. This study investigates the efficient removal of Anionic Actas Pink dye (AAPD), a major contributor to environmental pollution. Green adsorbents including lead oxide (PbO), zinc oxide (ZnO), cadmium oxide (CdO), and copper oxide (CuO) were synthesized via eco-friendly routes for AAPD removal. Maximum adsorption capacities (qe) were observed at pH 7 (PbO, ZnO, CdO) and pH 2 (CuO and native) with values of 83.83 mg/g at 100 ppm, 75.65 mg/g at 100 ppm, 70.50 mg/g 75 ppm, 61.21 mg/g at 150 ppm, and 52.69 mg/g at 150 ppm, respectively, using an adsorbent dose of 0.05 g/50 mL at temperature of 37°C, and 90 min contact time. Adsorption followed Langmuir isotherm for all adsorbents except native, with PbO also fitting Freundlich and Dubinin–Radushkevich isotherms. Kinetics adsorption data supported pseudo-second-order, while thermodynamic analysis indicated spontaneous and exothermic nature. Effects of electrolytes, surfactants, and desorption were also evaluated. Characterization through FTIR, SEM, and XRD confirmed the morphology and functional groups of these nano-quantum dots. Citrus limon peel-based biosynthesis offers sustainable, eco-friendly, and cost-effective alternatives, highlighting their potential for dye adsorption.

Structural, morphological and antibacterial for cadmium oxide nanoparticles prepared via pulsed laser ablation

Structural, morphological and antibacterial for cadmium oxide nanoparticles prepared via pulsed laser ablation

Compositional impacts of high CdO content on the structure and radiation shielding efficiency of CoO–Na2O–B2O3 glass system

Here, this study investigated the structural changes and radiation shielding efficiency of a borate glass host modified by varying cadmium oxide (CdO) concentrations. The glass composition consisted of boron oxide (B2O3; 80:56 mol%), sodium oxide (Na2O; 19.6 mol%), and cobalt oxide (CoO; 0.4 mol%), with cadmium oxide (CdO; 0:24 mol%). The glass structure was analyzed utilizing mass density and FT-infrared spectroscopy (FTIR) in the 400 to 1600 cm−1 range, while radiation shielding properties were investigated utilizing the online Phy-X software in the 0.284–1.333 MeV energy window. Notably, the addition of CdO significantly impacted the glass density, increasing it by approximately 93 % as the added CdO concentration rose from 0 to 24 mol% (i.e., from 2.507 g/cm3 to 4.849 g/cm3). FTIR analysis revealed a concurrent increase in BO4 structural units with increasing CdO/B2O3 ratios. This observation was supported by the calculated N4BO4/(BO3+BO4) ratio, which increased from 40.73% for the CdO-free sample to 52.00% for the highest CdO content. This increase in BO4 units, denser than BO3 units, explains the observed density increase. Conversely, the concentration of non-bridging oxygens decreased from 10.14% to 4.34% with increasing CdO contents, indicating a more tightly packed glass network. Radiation shielding studies demonstrated that increasing CdO concentration from 0 to 24 mol% enhanced the shielding efficiency, evidenced by a decrease in the half-value layer parameter (HVL). The radiation protection efficacy (RPE) also increased from 0.214 to 0.426 for the CdO-free sample to the sample containing 24 mol% CdO at the investigated energy level. This finding highlights the superior shielding capability of the CdO-rich sample. Furthermore, the transmission factor (TF) was investigated for a constant thickness of 0.75 cm for glasses. The CdO-rich sample exhibited a lower TF compared to the CdO-free sample, particularly at lower energies. This finding confirms that, for a given thickness and energy, raising the cadmium oxide content in the current composition leads to an observed mitigation in the transmitted radiation.

Large Mid‐Infrared Magneto‐Optic Response from Doped Cadmium Oxide at Its Epsilon‐Near‐Zero Frequency

AbstractThe epsilon‐near‐zero (ENZ) frequency regime of transparent conducting oxide materials is known to yield large enhancements in their optical nonlinearity and electro‐optic response. Here, Faraday rotation is investigated in Gd and In‐doped CdO films and it is found that the Verdet constant peaks at values >3 105 deg T−1 m−1 near the ENZ frequency, which is tunable in the wavelength range 2 < λ< 10 µm by varying the doping concentration. These results are among the highest reported to date in the mid‐infrared spectral range and are in good agreement with the Drude model, which confirms that the magneto‐optic response of doped CdO derives from its free carriers. The combination of a tunable Verdet constant, low optical loss compared to other plasmonic materials, and the ability to deposit CdO on Si with no loss in performance make this material a promising platform for integrated magneto‐optic and magnetoplasmonic devices that operate across the mid‐infrared.

Electrical behavior of polyvinyl alcohol filled by neodymium oxide and cadmium oxide nanoparticles synthesized via laser ablation for optoelectronic devices

Electrical behavior of polyvinyl alcohol filled by neodymium oxide and cadmium oxide nanoparticles synthesized via laser ablation for optoelectronic devices

Nebulized spray pyrolysis deposited CdO thin films for liquefied petroleum gas and ethanol gas sensor

High quality cadmium oxide (CdO) thin films were prepared through an inexpensive and simple nebulized Spray Pyrolysis (neb-SP) technique. The transparent conducting CdO thin films deposited at different substrate temperatures (TS) for the ethanol and liquefied petroleum gas (LPG) sensor application. XRD, SEM, UV–vis Spectroscopy and Hall Effect were done to study the structural, morphological, optical and electrical properties respectively. Polycrystalline nature thin films shows (1 1 1) cubic structure as the prominent peak. Surface morphology studies reveal that the grain size and roughness of the films are increased with increase in the substrate temperature. The average transmittance of the yellowish transparent CdO thin films is about 57%, thus the films are transparent in the visible region. The optical band gap (Eg) value of the CdO films increased from 2.16 to 2.28 eV with increase in the TS from 225 °C to 300 °C. The minimum value of electrical resistivity of the films is 1.40 × 10−3 Ωcm obtained at 275 °C. The neb-SP deposited CdO thin film (275 °C) shows maximum response to the ethanol and LPG gas sensitivity of 31.87% and 16.4% respectively at operating temperature of 573 K. Thus the results authenticate that the CdO thin films deposited low substrate temperature with high quality can be achieved via neb-SP technique compared to other wet chemical or physical method.

The Effective Capacitance Behaviour of Argon Plasma Exposed Al Dopped CdO Electrode Used in Efficient Metal ‐Air Batteries

AbstractThe impact of employing DC glow discharge plasma on aluminum‐doped cadmium oxide (Al‐doped CdO) electrodes is explored in the context of advanced energy storage, particularly focusing on Al‐air batteries. Utilizing various characterization techniques including XRD, FTIR, Raman spectroscopy, FESEM, and EDS, we identify significant changes in structure and morphology induced by plasma treatment, such as nano scale clustering, increased surface roughness, and higher oxidation levels. Electrochemical tests with a three‐electrode system shows remarkable improvements in charge storage capacity after plasma treatment, particularly with argon plasma, resulting in increased capacitance (1140 Fg−1), specific capacity (681 mAhg−1), and reduced charge transfer resistance (4.2 Ω), with notable changes in behavior, especially in potassium hydroxide (KOH) electrolyte.

A Study of Characteristics and Properties of Nano-metal Oxides (Zinc Oxide, Cadmium Oxide, Titanium Dioxide, Iron Oxide)

Nanotechnology is a rapidly developing scientific discipline with promise for enhancing human well-being via its applications in nanomedicine. It describes the technology used to accurately manipulate atoms and molecules to create new materials with dimensions that are on the nanoscale. The usual size range of nanoparticles (NPs) is 1-100 nm. Since nanoparticles are important in preventing infections, they can be used as therapeutic nanocarriers having antibacterial properties. This paper reviews the literature on the various production techniques, characteristics, and biological uses of several nano-metal oxides (iron oxide, titanium dioxide, zinc oxide, and cadmium oxide). The utilization of nanoparticles and their applications will grow due to the cost-effective ways available for biomodification. Because of their special qualities, nanoparticles are helpful in several scientific domains, including biology, materials science, engineering, electronics, and food science. Researchers have become interested in nanotechnology because of its benefits, particularly its potential uses in the healthcare system for improved diagnosis and treatment.

Conversion of preferred crystalline orientation by annealing and its impacts on the structural, electronic, and optical properties of pulsed laser-deposited CdO thin films

The impact of annealing on the preferred crystalline orientation as well as the structural, electronic, and optical properties of pulsed laser-deposited 150 ± 3 nm thick cadmium oxide (CdO) films was studied. X-ray diffraction analysis revealed that the annealed CdO films have smaller crystallite sizes, as their molecules at the grain boundaries possessed enough kinetic energy to rearrange their preferred crystalline orientation between (111) and (200). The atomic force microscopy and field emission scanning electron microscopy analyses revealed an enhancement in the active surface area with optimized grain boundaries by annealing which facilitates gas adsorption/desorption. DC electrical conductivity depends on the annealing process and reveals two different conduction mechanisms. The direct optical energy gap was decreased from 3.41 eV to 2.76 eV by annealing at 473 K which is greater than the theoretical value, i.e. 2.2 eV, for bulk CdO. The findings agree with the Burstein-Moss effect as a result of the increased carrier concentration following the generation of numerous oxygen vacancy sites and Cd interstitials. However, mutual charge carrier-impurity interaction and charge carrier Columb interaction contributed to narrowing the band gap by increasing the annealing temperature. The enhanced values of Urbach energy, optical packing density, dispersion parameters, optical conductivity, dissipation factor, oscillator strength, and lattice dielectric constant supported the effectiveness of the annealing process on tailoring optoelectronic responses in the infrared region for the CdO thin films for use in optoelectronic devices. Moreover, the calculated linear optical susceptibility, and nonlinear constants (i.e. third-order optical susceptibility and nonlinear refractive index) were the highest for CdO films annealed at 473 K. The improved value of the figure of merit, solar material protection factor, and solar skin protection factor for the CdO films, annealed at 473 K supports its use in several photovoltaic applications, including solar cells.

Influence of multi-doping (Zn and Sn) on the optical, and electrical properties of spray-deposited CdO thin films

This investigation has been focused on the spray-deposited pure cadmium oxide (CdO) thin films and also doped with zinc (Zn) and tin (Sn), as a transparent conducting oxide for optoelectronic applications. By varying the concentration of Sn (0–2%) into CdO, the microstructural, morphological, and optoelectronic properties were investigated. XRD spectra confirmed the polycrystalline cubic structure of the pure, doped, and co-doped CdO films. SEM investigation reveals the crack-free homogeneous cauliflowers-like morphology of the fabricated thin films. The existence of elemental compositions such as Cd, Zn, Sn, and O in the prepared films was confirmed by EDS analysis. All of the doped and co-doped CdO films showed good transparency in the visible range. Moreover, a slight increment has been found in the optical band gap from 2.43 eV to 2.50 eV with increasing Sn concentration, which can be explained by the Burstein-Moss phenomena. A decrement of Urbach energy was noted for an increased concentration of Sn. Besides, Zn and Sn (1 %) co-doped films exhibited the lowest electrical resistivity value 4.09×10−4 Ω-cm among other doped compositions. However, the addition of Zn and Sn into CdO thin films enhanced the optoelectronic properties.

Tailoring epsilon-near-zero wavelength and nonlinear absorption properties of CdO thin films by Mo doping

Cadmium oxide (CdO) has recently attracted attention as a material with controllable properties tailored for optoelectronic and nanophotonic devices due to its superior mobility. However, its potential application in near-infrared (NIR) remains to be explored. In this work, we demonstrate that the epsilon-near-zero (ENZ) wavelength and nonlinear optical properties of CdO films can be effectively tuned by Mo doping. The results show that Mo doping increases the electron concentration as well as improve the crystalline quality of CdO. With increasing Mo doping, we achieve blueshifts of the ENZ wavelength from 2.89 to 1.56 μm. The nonlinear absorption (NLA) behavior at 1550 nm changes from reverse saturable absorption to saturable absorption with increasing Mo content. Moreover, significant improvement in NLA performance with nonlinear absorption coefficient β = −72 cm/GW is observed at the highest doping content. Our work shows that doped CdO films with tunable optoelectrical and nonlinear optical properties can be an ideal candidate for optoelectronic and nanophotonic application in the NIR region.

Assessment of the ecotoxicity of heavy metal contaminants on aquatic organisms: A reviewon the impact of Lead, Chromium, Cadmium, Zinc and Mercury

Heavy metal ecotoxicity has been recognized to be a major threat to aquatic organisms and there are several health risks associated with it.This in-depth review investigation explores the critical issue of heavy metals pollution, concentrating on the hazardous effects of chromium, cadmium, lead, mercury, and zinc oxide nano particles on aquatic species.

Magneto-optical transport properties of the nanostructured transparent conducting oxides

A comparative study of the optical absorption properties of the nanostructured transparent conducting oxides (TCOs) such as zinc oxide (ZnO), cadmium oxide (CdO), and gallium oxide (Ga2O3) in the presence of a magnetic field B has been performed. The cyclotron resonance absorption power in the TCO materials of the symmetric Pöschl–Teller quantum well (SPTQW) and the full width at half maximum (FWHM) are obtained by applying the operator projection method, the confined phonon model of Huang–Zhu, and the profile technique. Our main results are as follows: The order of the absorption power intensity in these TCOs from strongest to weakest is Ga2O3, ZnO, and CdO, whereas that of the FWHM from largest to smallest is CdO, ZnO, and Ga2O3. This is because the optical phonon frequency in CdO is the smallest, while that in Ga2O3 is the largest. The influences of the magnetic field strength, the thickness, and the temperature on the FWHM in ZnO, CdO, and Ga2O3 become more significant as the phonon is confined. The optical absorption properties of the TCOs are remarkably enhanced due to the confinement of phonon, and those of CdO are the most dominant among the Ga2O3, ZnO, and CdO. The results of our study can provide particular insights for the design of optoelectronic devices.

DEFECT-ASSISTED TUNABLE LUMINESCENT FEATURES OF SILAR-GROWN CADMIUM OXIDE FILMS

DEFECT-ASSISTED TUNABLE LUMINESCENT FEATURES OF SILAR-GROWN CADMIUM OXIDE FILMS