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Cadmium oxide

Cadmium oxide (CdO) is an consisting of and oxygen, typically appearing as an odorless, brown amorphous powder or dark brown cubic crystals that are insoluble in . It has a molecular weight of 128.41 g/mol, a of approximately 900–1000°C, and sublimes at 1559°C, with a specific gravity of 8.15 for the crystalline form. This compound is produced industrially by burning cadmium metal in air or through the of other cadmium compounds. Cadmium oxide finds applications in , the manufacture of nickel-cadmium batteries (accounting for about 50% of cadmium use), pigments for ceramics and plastics, semiconductors, glassmaking, and as a catalyst or stabilizer in various alloys and materials. It reacts violently with magnesium when heated and decomposes to emit toxic cadmium fumes, necessitating careful handling in controlled environments. Despite its utility, cadmium oxide is highly toxic and classified as a carcinogen by the International Agency for Research on Cancer, primarily posing risks through as fumes or dust. Acute can cause severe respiratory irritation, , , and potentially fatal , with a lethal dose estimated at 2,500 mg/m³ for 1 minute and an immediately dangerous to life or health (IDLH) concentration of 9 mg Cd/m³. Chronic leads to fibrosis, kidney damage, , and increased risk of and cancers, with no-observed-adverse-effect levels (NOAEL) for respiratory effects as low as 0.025 mg/m³ in . Occupational limits are stringent, such as OSHA's of 0.005 mg/m³ over 8 hours.

Properties

Crystal structure

Cadmium oxide (CdO) primarily adopts a cubic rock salt (NaCl-type) , characterized by a face-centered cubic where Cd²⁺ ions are octahedrally coordinated by six O²⁻ anions, and vice versa, forming interpenetrating of CdO₆ and OCd₆ octahedra. This structure belongs to the Fm3m (No. 225), with an experimental parameter of approximately 0.4695 nm (4.695 ) at . The cubic phase is the thermodynamically stable form under ambient conditions, confirmed by () patterns featuring characteristic peaks such as (111) at around 2θ ≈ °, (200) at 2θ ≈ 38°, and (220) at 2θ ≈ 55°, corresponding to the rock salt . A metastable hexagonal polymorph exists, which can be synthesized under specific high-temperature annealing conditions (e.g., 900°C in oxygen) or , exhibiting P6₃mc and distinct peaks like (101) at 2θ ≈ 37° and (102) at 2θ ≈ 49°. Doping with elements such as (In) or (Sn) introduces lattice distortions in the cubic structure due to differences in ionic radii, leading to slight expansions or contractions of the lattice parameter and enhanced electrical conductivity in variants used for transparent electrodes. These structural modifications contribute to the material's n-type semiconducting behavior by altering defect states and carrier mobility.

Physical properties

Cadmium oxide (CdO) typically appears as brown or red crystals in its crystalline form or as a colorless amorphous powder, depending on the preparation method. The density of crystalline CdO is 8.15 g/cm³ at 25 °C. The crystalline form of CdO has a melting point of approximately 1427 °C, while the amorphous form decomposes around 900–1000 °C; its boiling point is not well-defined due to thermal decomposition or sublimation at high temperatures around 1559 °C. It is insoluble in water, with a very low solubility of about 4.8 mg/L at 18 °C, corresponding to an effective solubility product (Ksp) on the order of 10⁻¹⁴ based on equilibrium with cadmium hydroxide. As a semiconductor, CdO exhibits n-type conductivity with a direct band gap ranging from 2.2 to 2.5 eV at room temperature. The coefficient of CdO is 14 × 10⁻⁶ K⁻¹. Pure CdO is diamagnetic, with a of -0.000030.

Chemical reactivity

Cadmium oxide (CdO) exhibits amphoteric , dissolving in both acidic and alkaline solutions to form soluble cadmium species. In acidic media, it reacts with to yield cadmium chloride and , as represented by the equation: \text{CdO} + 2\text{HCl} \rightarrow \text{CdCl}_2 + \text{H}_2\text{O} This reaction proceeds via protonation and dissolution, with solubility increasing as pH decreases due to the formation of Cd²⁺ ions. In strong basic conditions, CdO reacts with sodium hydroxide to form sodium tetrahydroxocadmate(II), according to: \text{CdO} + 2\text{NaOH} + \text{H}_2\text{O} \rightarrow \text{Na}_2[\text{Cd(OH)}_4] This amphoteric dissolution in bases involves the formation of hydroxo complexes, enhancing solubility at high pH values. In CdO, cadmium adopts the +2 oxidation state (Cd(II)), which is the predominant and stable valence for cadmium compounds under ambient conditions. However, this state can be reduced to metallic cadmium (Cd(0)) at elevated temperatures, typically through carbothermal or reduction processes occurring around 500–650 °C, depending on the . CdO demonstrates thermal stability up to high temperatures but undergoes decomposition in vacuum environments above approximately 900–1100 °C, yielding metallic cadmium and oxygen gas via the reversible reaction: $2\text{CdO} \rightleftharpoons 2\text{Cd} + \text{O}_2 This endothermic decomposition is utilized in high-temperature processes, such as solar thermochemical cycles for hydrogen production, where temperatures exceeding 1100 °C facilitate significant rates of dissociation. CdO reacts with halogens and other non-metals at elevated temperatures to form binary cadmium compounds. For instance, heating CdO with chlorine gas produces cadmium chloride (CdCl₂), while reactions with sulfur yield cadmium sulfide (CdS). These transformations involve displacement of oxygen, often requiring temperatures above 600 °C to overcome the stability of the oxide lattice. The of CdO in aqueous solutions is highly -dependent, reaching a minimum of approximately 3 × 10⁻⁷ mol dm⁻³ in the neutral to mildly alkaline range ( 10–13), where it exists primarily as the insoluble Cd(OH)₂. At lower , rises due to dissolution forming Cd²⁺, while at higher (>13), it increases again through the formation of soluble hydroxo complexes such as [Cd(OH)₃]⁻ and [Cd(OH)₄]²⁻, with stability constants indicating predominance of the tetrahydroxo species in concentrated .

Production

Industrial production

Cadmium oxide is primarily produced as a byproduct of processes, where cadmium impurities in zinc-bearing ores, such as , are recovered during . In this pyrometallurgical method, the ores are roasted in air to convert to oxide, volatilizing as oxide fumes that are captured in dusts or filters; these are then leached with to form sulfate, which is purified and electrolyzed or distilled to metal before controlled oxidation to oxide. To a lesser extent, oxide arises from lead and refining of ores like . An alternative industrial route involves the of , where CdCO₃ is heated to decompose into CdO and CO₂, typically at temperatures between 300°C and 500°C to ensure complete conversion while minimizing . Another direct method is the oxidation of metal, achieved by the metal in a under controlled air flow and vaporizing it into a heated chamber, where it reacts with oxygen according to 2Cd + O₂ → 2CdO, producing fine oxide powder suitable for industrial applications. Purification of the resulting cadmium oxide is essential to achieve commercial grades of 99–99.9999% purity, focusing on removing common impurities such as zinc oxide and lead oxide through with acids or alkalis, followed by and steps during the upstream metal recovery phase. Thallium and other trace metals are similarly separated via cementation or solvent extraction in the intermediate stage. In 2023, global refinery production of , from which oxide is derived, was estimated at 23,000 metric tons, with major producers including (9,000 tons), (1,800 tons), (1,800 tons), and (4,000 tons). Production has remained relatively stable despite stringent environmental regulations on cadmium's , partly due to growing demand for in solar panels. Cadmium oxide production volumes are smaller and tied to specific end-uses.

Laboratory preparation

Cadmium oxide can be prepared in the laboratory through the of , where Cd(OH)₂ decomposes to form CdO and according to the Cd(OH)₂ → CdO + H₂O. This process typically occurs at temperatures around 400 °C, ensuring complete conversion to the oxide phase, as confirmed by (TGA) which shows a significant corresponding to between 200–450 °C. Another common laboratory method involves precipitation from aqueous solutions, such as adding to solution to first form precipitate: Cd(NO₃)₂ + 2NaOH → Cd(OH)₂ + 2NaNO₃. The resulting is then filtered, washed, dried, and calcined at elevated temperatures (typically 400–500 °C) to yield CdO powder. This approach allows for high purity and is suitable for small-scale synthesis, with used to optimize conditions by identifying the exact temperature for maximum yield. For nanostructured CdO, sol-gel and hydrothermal methods are employed to produce nanoparticles with controlled sizes in the 5–50 nm range. In sol-gel synthesis, cadmium acetate or nitrate is hydrolyzed in the presence of surfactants like sodium dodecyl sulfate (SDS) or polyethylene glycol to form a sol, which is then gelled, dried, and calcined to yield uniform nanoparticles. Hydrothermal synthesis similarly uses sealed reactors at 100–200 °C with surfactants to regulate particle growth, preventing agglomeration and achieving sizes around 10–30 nm, as verified by transmission electron microscopy (TEM). These techniques enable precise size control for research applications, with TGA aiding in determining optimal calcination temperatures to minimize defects. Vapor deposition techniques, such as (CVD), are used for preparing CdO thin films in laboratory settings. This involves reacting a cadmium precursor, like , with an oxygen source (e.g., O₂ or ) at substrate temperatures of 300–500 °C, resulting in polycrystalline films with controlled thickness. Yield optimization in CVD focuses on precursor flow rates and temperature gradients to achieve high deposition efficiency (up to 80–90%), while characterization techniques like on precursor mixtures help predict decomposition profiles for consistent film quality.

Applications

Transparent conducting films

Doped cadmium oxide (CdO) thin films are widely utilized as transparent conducting oxides (TCOs) in optoelectronic devices, offering a combination of high electrical and optical essential for transparent electrodes. Doping with (In), tin (Sn), or (F) significantly enhances carrier concentration and mobility, enabling sheet resistances below 10 Ω/sq while maintaining average transmittances greater than 80% across the (400–700 nm). For instance, In-doped CdO achieves electron concentrations exceeding 10^{21} cm^{-3} and mobilities over 120 cm²/V s through appropriate doping levels, balancing with low absorption. These films are deposited via techniques such as radio-frequency , spray , or deposition, yielding uniform layers 50–500 nm thick suitable for device integration. Spray , for example, allows F-doped CdO preparation from cadmium acetate precursors, producing films with improved electrooptical properties at substrate temperatures around 300–400°C. Sn-doped variants via thermal evaporation exhibit resistivities as low as 1.6 Ω cm at 2% doping, with thicknesses around 200–300 nm ensuring minimal optical losses. deposition of In-doped CdO results in 230 nm films with resistivity of 7.2 × 10^{-5} Ω cm and of 3.1 Ω/□. In solar cells, doped CdO serves as a window layer in CdTe , promoting efficient light entry and charge extraction at the ; CdO/CdTe structures have demonstrated photovoltaic operation with contributions to overall module efficiencies up to 20%. Similar roles in CIGS devices leverage CdO's high mobility for reduced series resistance. Beyond , these films function as electrodes in displays (LCDs) and touch screens, where their transparency and low resistivity support flexible, large-area applications. Key performance metrics include the Haacke figure of merit, \phi_{TC} = \frac{T^{10}}{R_s}, where T is the visible transmittance and R_s is the sheet resistance; optimized CdO films reach values of 5.69 × 10^{-1} Ω^{-1}, indicating superior optoelectronic balance compared to undoped variants. Humidity stability remains challenging, as moisture exposure degrades mobility in undoped and lightly doped films due to defect interactions, though In-doping and controlled deposition mitigate this, preserving conductivity under relative humidity up to 50% for extended periods. The foundational report of CdO thin films as TCOs dates to , when sputtered layers oxidized to form transparent conductors, with doping advancements in the mid-20th century enabling high-performance variants for modern devices.

Cadmium

Cadmium oxide serves as a key precursor in the preparation of electrolytes for cadmium , where it is dissolved to form soluble cadmium salts suitable for . In baths, which are the most commonly used for this process, cadmium oxide is reacted with to produce sodium cadmium cyanide (Na₂Cd(CN)₄), typically at concentrations of 21–42 g/L CdO and 87–150 g/L NaCN, resulting in an alkaline solution with a of 11–13. Acid baths, an alternative to systems, are prepared by dissolving cadmium oxide in according to the reaction CdO + H₂SO₄ → CdSO₄ + H₂O, yielding cadmium sulfate electrolytes with compositions such as 20–30 g/L CdO and approximately 80 mL/L of 66° Baume H₂SO₄, operated at a of 3–5. The process involves immersing or substrates in the prepared bath as the , with anodes, and applying a to deposit a uniform layer. Electrodeposition occurs at current densities of 1–5 A/dm² and temperatures of 20–30°C, producing coatings typically 5–25 μm thick, depending on the application and environmental exposure requirements. baths offer superior throwing power and uniformity on complex geometries, while acid baths provide brighter deposits but require more precise control to avoid . Cadmium platings exhibit excellent sacrificial corrosion protection, preferentially corroding to shield the underlying metal, and outperform coatings in marine and salt-laden environments due to their lower potential with . Additionally, the coatings provide inherent , reducing and improving assembly for threaded fasteners and components. Historically, cadmium was extensively used in and applications for its reliability in harsh conditions, but restrictions imposed by the European Union's and REACH directives since the mid-2000s have limited its application in non-exempt sectors, prompting shifts to alternatives like zinc-nickel alloys.

Other industrial uses

Cadmium oxide serves as a key precursor in the synthesis of various cadmium salts, particularly those used in pigments and phosphors. For instance, it reacts with to produce (), a bright employed in paints, ceramics, and inks due to its and vibrant color. Similarly, cadmium oxide is incorporated into phosphor formulations for display technologies, where it contributes to green-emitting materials in older televisions by forming compounds like or selenide phosphors that exhibit efficient under electron excitation. In the ceramics and industries, cadmium oxide functions as a and colorant in glazes and enamels, enhancing melt and imparting specific hues when combined with other elements. It promotes a glossy finish in fired enamels by increasing the , thereby improving the brilliancy and durability of decorative coatings on and surfaces. When used with , it yields red tones in glazes, while sulfur combinations produce orange shades, though these applications require precise control to avoid defects like pinholes. Its role as a helps lower the firing temperature, making it valuable for vitreous enamels on metal substrates. Cadmium oxide, often in combination with zinc oxide, has been utilized as a stabilizer in (PVC) plastics to inhibit degradation from and light exposure during processing. These CdO/ZnO compounds prevent discoloration and embrittlement by neutralizing released from PVC, extending the material's lifespan in applications like pipes and cables. However, it was voluntarily phased out by the PVC industry as part of the Vinyl 2010 commitment, completed in the EU-15 by 2001 and in the EU-27 by the end of 2007, with alternatives like calcium-zinc systems adopted instead. In 2024, exemptions were granted under for cadmium in recovered rigid PVC for use in electrical and electronic windows and doors. As a catalyst, cadmium oxide facilitates certain reactions, including dehydrogenation of hydrocarbons and oxidation processes. It exhibits activity in hydrogen transfer reactions, enabling the conversion of alcohols to aldehydes or the dehydrogenation of cyclic compounds under moderate conditions. In modern applications, cadmium oxide nanoparticles have been explored for immobilizing enzymes like to promote selective oxidation in the synthesis of organic compounds, such as from aromatic precursors. Recent studies (2020–2025) have also explored CdO nanoparticles for photocatalytic applications, such as pollutant degradation and via . In niche applications, cadmium oxide contributes to the production of nickel-cadmium (Ni-Cd) battery electrodes through processes that convert it to metallic cadmium for the material, providing high and rechargeability in , medical, emergency, and other exempt applications. Additionally, it is incorporated into rods and electrodes to enhance stability and deposit cadmium coatings that improve resistance on components.

Health and environmental impacts

Toxicity to humans

Cadmium oxide primarily enters the through of its fumes, which is the most hazardous exposure route, particularly in occupational settings such as , , or production where the compound forms fine, inhalable particles. can occur via contaminated or water, while dermal absorption is possible but contributes minimally to overall toxicity due to the compound's low skin permeability. Acute exposure to cadmium oxide fumes causes immediate respiratory irritation, including coughing, , and , often progressing to severe and within hours to days. These effects were first recognized in the among industrial workers exposed to cadmium oxide smoke during metal processing. High-dose can be fatal, with symptoms resembling initially but escalating to life-threatening lung damage. Chronic exposure to cadmium oxide leads to kidney damage, manifesting as and impaired renal function, as the compound accumulates in the and disrupts tubular reabsorption. It also causes bone demineralization, contributing to conditions like , characterized by severe , bone pain, and fractures, historically observed in populations with prolonged cadmium contamination. Additionally, long-term inhalation increases the risk of , with cadmium oxide classified as a carcinogen by the International Agency for Research on Cancer due to sufficient evidence from occupational cohort studies. Cadmium from cadmium oxide exhibits significant in humans, with a of 10–30 years, primarily targeting the kidneys and liver where it binds to and persists long after exposure ceases. To mitigate occupational risks, the (OSHA) sets a (PEL) of 5 μg/m³ (as cadmium) for an 8-hour time-weighted average for cadmium oxide fumes, with medical surveillance required for exposed workers showing symptoms like elevated urinary cadmium levels. In July 2025, OSHA proposed revisions to requirements under the cadmium standard to allow additional types for better compliance. Treatment for cadmium oxide poisoning focuses on supportive care, including for respiratory distress, and with calcium disodium EDTA to enhance urinary excretion in severe acute cases, though its efficacy is limited for chronic accumulation.

Environmental effects and regulations

Cadmium oxide, as a source of cadmium ions in environmental media, is non-biodegradable and exhibits high persistence in and water due to its low and resistance to natural degradation processes. This persistence allows cadmium to accumulate over time, posing long-term risks to ecosystems. Cadmium bioaccumulates in food chains, with notable uptake in organisms such as , where concentrations can reach levels thousands of times higher than in surrounding water, and in crops grown on contaminated soils, facilitating transfer to higher trophic levels. It is particularly toxic to aquatic life, with acute LC50 values for sensitive fish species, such as (Oncorhynchus mykiss), often below 1 mg/L (e.g., 0.8–10 μg/L normalized to 100 mg/L hardness), leading to damage, reduced growth, and mortality. Soil and water contamination by cadmium oxide primarily arises from runoff and discharges, which introduce into and terrestrial systems. In soils, this contamination promotes plant uptake, especially in root and grains, enabling trophic transfer through herbivores and predators in the . production of cadmium oxide, involving and , serves as a key source of such through airborne emissions and . Global regulations aim to mitigate cadmium releases and uses. Under the EU's REACH Regulation (Annex XVII), cadmium and its compounds, including cadmium oxide, are restricted in plastics to a maximum concentration of 0.01% by weight, with broader bans on their use in most plastic articles effective since December 2011 (extending prior restrictions from 1992 on certain PVC types). The EU RoHS Directive similarly limits cadmium to 0.01% in homogeneous materials of electrical and electronic equipment to prevent environmental release during disposal. In the United States, the Toxic Substances Control Act (TSCA) authorizes regulation of cadmium compounds, while the EPA enforces effluent limitations under the Clean Water Act, typically below 0.1 mg/L for cadmium in industrial discharges such as from facilities. The FDA's , updated in 2024, aims to reduce childhood exposure to contaminants including cadmium in foods like baby foods. Internationally, the 1998 Protocol on to the Convention on Long-Range Transboundary requires parties to reduce cadmium emissions from sources like metal production and waste incineration, targeting levels below 1990 baselines. Remediation strategies for cadmium oxide-contaminated sites focus on reducing and mobility. employs hyperaccumulator plants, such as Noccaea caerulescens (formerly Thlaspi caerulescens), to extract from , with reported removal rates of approximately 1–5% per growing season in moderately contaminated soils, potentially accumulating to higher totals over multiple harvests. Chemical stabilization, using amendments like phosphates or , immobilizes by forming insoluble precipitates, thereby preventing into and uptake by . These approaches are often combined for enhanced efficacy in mining-impacted areas.

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