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Strontium oxide

Strontium oxide, with the SrO and CAS number 1314-11-0, is an composed of and oxygen, appearing as a white, crystalline powder that is hygroscopic and reacts exothermically with water to form . It has a molecular weight of 103.62 g/mol, a of 4.7 g/cm³ at 25 °C, a of 2,531 °C, and a of approximately 3,000 °C, making it highly and suitable for high-temperature applications. The compound is insoluble in organic solvents like and acetone but dissolves in fused . Strontium oxide is primarily produced industrially by the (calcination) of (SrCO₃) at temperatures above 1,100 °C, which releases and yields pure ; alternatively, it can be obtained by direct oxidation of strontium metal in air, though the former method is more common due to the availability of celestite (SrSO₄) as a natural source for compounds. This process ensures high purity for commercial grades, often exceeding 99% trace metals basis. Key applications of strontium oxide include its use as a and modifier in manufacturing to enhance , , and chemical durability, particularly in optical glasses; about 40% is used in ceramics for producing strontium-based magnets and another 40% in for red flame coloration via strontium salts, with among other uses; it is also employed as a catalyst in and molecular solar storage systems. Emerging research explores its role in biomaterials for bone repair due to strontium's bioactivity in promoting . Due to its strong basicity, strontium oxide is corrosive to skin and eyes, classified as a skin corrosion hazard (Skin Corr. 1B), and requires handling with protective equipment like gloves and respirators; it is moisture-sensitive and should be stored in a dry environment to prevent unwanted hydrolysis.

Properties

Physical properties

Strontium oxide (SrO) appears as a white, odorless powder or, in its crystalline form, as colorless cubic crystals. It has a molar mass of 103.619 g/mol. The density of strontium oxide is 4.70 g/cm³ at 25 °C. Its melting point is 2,531 °C. The is approximately 3,000 °C, at which point begins. The is 1.862 (at 656 nm). Strontium oxide is insoluble in acetone and , slightly soluble in , and reacts with water to form .

Chemical properties

Strontium oxide (SrO) is classified as a strongly metal , a characteristic attributed to the large of the Sr²⁺ cation, which results in low and reduced polarizing power compared to smaller group 2 cations. This low enhances the ionic nature of SrO, promoting its behavior by facilitating the donation of oxide ions (O²⁻) in reactions. The strength among group 2 oxides follows the trend SrO > CaO > MgO, increasing down the group as ionic size grows and decreases, making heavier oxides like SrO more effective at accepting protons or interacting with acidic species. SrO exhibits general stability in dry air but shows a tendency to hydrate slowly upon exposure to moist conditions, yielding as the hydrolysis product. Additionally, it can absorb CO₂ from the atmosphere over time, gradually forming due to its strong basic nature. is soluble in fused , reflecting its compatibility with alkaline media.

Structure and thermochemistry

Crystal structure

Strontium oxide (SrO) crystallizes in the rock salt () structure, characterized by a face-centered cubic in which Sr²⁺ and O²⁻ ions alternate along each of . This arrangement results in a highly symmetric ionic solid, often appearing as cubic . The crystal belongs to the Fm\overline{3}m (No. 225), with a parameter a = 5.16 Å at room temperature. In this structure, each Sr²⁺ ion is octahedrally coordinated to six O²⁻ ions, and vice versa, forming a network of - and corner-sharing octahedra with no tilting. The Sr–O bond length is approximately 2.58 Å, consistent with the geometry of the cubic . The bonding in SrO is predominantly ionic, driven by the substantial electronegativity difference between strontium (0.95 on the Pauling scale) and oxygen (3.44), which exceeds the threshold for ionic character (Δχ > 1.7). No polymorphic forms of SrO are reported under standard ambient conditions, where the rock salt phase remains thermodynamically stable.

Thermodynamic properties

Strontium oxide exhibits significant thermodynamic stability characteristic of group 2 metal oxides, with its standard enthalpy of formation ΔH_f° at 298 K being -592.0 kJ/mol, indicating a highly exothermic formation process from the elements. This value reflects the strong ionic bonding in the rock-salt structure, contributing to the compound's resistance to thermal decomposition under standard conditions. The standard Gibbs free energy of formation ΔG_f° at 298 K is -561.4 kJ/mol, further underscoring the spontaneity of its formation and its thermodynamic favorability relative to the constituent elements. The S° of solid at 298 is 57.2 J/mol·, a value derived from low-temperature measurements that accounts for the vibrational contributions in the . At the same temperature, the at constant pressure C_p is 44.3 J/mol·, which increases with temperature due to enhanced excitations, providing insight into the material's response in high-temperature applications. SrO demonstrates high thermal stability, with a melting point of approximately 2800 K and an enthalpy of fusion of 80.95 /, requiring substantial energy input to disrupt the solid lattice. The enthalpy of vaporization is notably high, consistent with the compound's nature. Compared to other group 2 oxides, SrO's thermodynamic stability is intermediate: its formation enthalpy is less exothermic than that of CaO (-635.1 /) but more so than BaO (-548.0 /), reflecting a trend of decreasing down the group due to increasing ionic radii. This positions SrO as stable for many industrial processes but less so than lighter analogs like MgO in extreme oxidizing environments.

Production

Industrial production

Strontium oxide is primarily produced on an industrial scale through the of , which is itself derived from celestite (SrSO₄). Celestite is processed via the black ash method, where it is calcined with at approximately 1,100°C to form strontium (), followed by reaction with or soda ash to precipitate (SrCO₃). This SrCO₃ is then calcined in a at temperatures ranging from 1,150°C to 1,300°C, yielding and CO₂ according to the reaction SrCO₃ → SrO + CO₂. The decomposition is thermodynamically favorable above 1,100°C due to the endothermic nature of the process, which requires careful control to achieve complete conversion. To prevent partial melting and agglomeration during calcination, finely divided carbon (at least 8% by weight, such as calcined ) is added to the SrCO₃ charge, reducing the partial pressure of CO₂ and lowering the (195 kJ/mol). The process is energy-intensive, demanding high-temperature kilns with significant fuel input for sustained heating, though carbon addition improves efficiency by facilitating gas evolution and minimizing . Optimal conditions include 15% metallurgical at 1,200°C for maximum yield, with the product cooled and ground to desired . Purification of the resulting SrO involves hydration to strontium hydroxide (Sr(OH)₂), dissolution in water, and leaching to remove impurities such as sulfates and other residuals from the ore, followed by re-calcination if needed for high-purity applications. An alternative, less common method is the direct oxidation of strontium metal in air, which produces SrO exothermically but is rarely used industrially due to the high cost and limited availability of strontium metal. Historically, major production occurred in the United States (e.g., by Chemical Products Corporation) and China, with global output tied to demand in glassmaking and electronics; U.S. processing relied on imported celestite, while China's capacity dominated world supply in the early 2000s. As of 2024, there is no domestic strontium mining or large-scale carbonate production in the United States, with small quantities of downstream chemicals like SrO produced from imports; global celestite production is led by Spain (200,000 tons), Iran (200,000 tons), and China (80,000 tons).

Laboratory preparation

Strontium oxide () can be prepared in the laboratory through the direct of metal in a controlled oxygen atmosphere. The reaction proceeds as 2Sr + O₂ → 2, typically conducted by igniting small pieces of strontium metal in a pure oxygen stream or enclosed chamber to minimize exposure to , which would otherwise form strontium (Sr₃N₂) as a contaminant. This method yields high-purity powder, with the product appearing as a white solid, though care must be taken to handle the highly reactive metal under inert conditions prior to ignition. Another common laboratory route involves the of (Sr(NO₃)₂) at temperatures between 570°C and 800°C, following the equation Sr(NO₃)₂ → + 2NO₂ + ½O₂. The nitrate is heated in a under air or oxygen flow, often in a or , to ensure complete decomposition without intermediate nitrite formation, resulting in a single-stage process. Similarly, strontium (SrC₂O₄) can be decomposed at 500–800°C to form via sequential steps involving loss of and CO₂, ultimately yielding the oxide after prolonged heating. These decompositions are performed in open or ventilated setups to safely vent gaseous byproducts like NO₂, which is toxic and reddish-brown. A hydration-dehydration cycle provides an alternative for preparing anhydrous SrO from strontium hydroxide (Sr(OH)₂), heated to approximately 500–700°C to drive off water: Sr(OH)₂ → SrO + H₂O. The hydroxide is typically dried in a muffle furnace under dry air, with the temperature controlled to avoid partial hydration or carbonation from atmospheric CO₂. To maintain purity in all thermal methods, carbon contamination is prevented by using non-carbon crucibles (e.g., alumina or platinum) and conducting reactions in oxygen-enriched or air atmospheres rather than reducing environments. Yields are generally high, exceeding 95% for well-controlled decompositions, producing fine white powders suitable for research. The resulting SrO is characterized using X-ray diffraction (XRD) to confirm the cubic rock-salt crystal structure and phase purity, with characteristic peaks at 2θ values around 30.1°, 34.8°, and 50.4° corresponding to the (111), (200), and (220) planes, respectively. This technique distinguishes SrO from potential impurities like unreacted precursors or hydrates. While strontium carbonate serves as a common industrial precursor, laboratory syntheses prioritize pure reagent salts for higher control and purity.

Applications

In electronics and glassmaking

Strontium oxide plays a critical role in the formulation of cathode-ray tube (CRT) glass, particularly in color televisions and monitors, where it is incorporated at concentrations of approximately 8-12% in the panel (faceplate) glass to absorb X-rays generated by the electron beam and prevent glass discoloration or browning. In the United States, strontium was incorporated in the faceplate and funnel glass of color CRT devices to meet federal radiation safety standards until the widespread adoption of liquid crystal display (LCD) technology in the mid-2000s. Lower levels of SrO, around 0.5-2%, are also present in funnel glass to contribute to overall radiation shielding. The addition of SrO enhances key optical and mechanical properties of specialty glasses used in , such as increasing the for improved light transmission in components and boosting chemical durability to withstand environmental exposure during and use. Its basicity further aids as a in glass melting processes, lowering the required temperatures. In lead-free formulations, SrO serves as a partial replacement for lead (PbO) in funnel , providing effective shielding while reducing toxicity, as seen in experimental compositions for televisions produced until around 2010. The decline of technology in favor of flat-panel displays after the early 2000s significantly reduced demand in , though trace amounts persist in -based monitors and systems. Despite this shift, 's contributions to radiation absorption and glass stability remain foundational in historical display production.

Other industrial uses

Strontium oxide serves as a flux in the production of ceramics and refractories, where it lowers melting points and enhances workability by promoting better fusion of materials during firing. This property makes it valuable for formulating glazes that achieve high gloss and craze resistance at stoneware temperatures around cone 1. In refractory applications, its addition improves thermal stability and reduces viscosity, facilitating the manufacture of durable high-temperature materials. In , strontium oxide is employed to derive strontium salts, such as , which impart a brilliant to and flares when combusted. This coloration arises from the excitation of ions in the , making it essential for vibrant displays in signals and entertainment . Strontium compounds, such as , aid in the electrolytic production of by removing impurities like lead, contributing to higher-purity zinc metal output. Their role leverages the ability to form separable phases with contaminants during refining. Strontium oxide plays a key role in the synthesis of materials for superconductors and ferrites, enhancing magnetic properties; for instance, it is a precursor in producing (SrTiO₃), a used as a in high-temperature superconducting devices. In ferrites, it is sintered with to create permanent ceramic magnets with strong magnetic performance. Strontium oxide has a minor application in lubricants, where it contributes to high-temperature in certain formulations, and serves as a in , notably for from vegetable oils. These catalytic uses exploit its basic surface sites for efficient reaction promotion under mild conditions. U.S. apparent consumption of strontium compounds is approximately 4,700 tons (as of 2023), driven mainly by its role in specialty chemicals and .

Emerging applications

Strontium oxide is being explored in biomaterials for repair, leveraging 's bioactivity to promote and regeneration in scaffolds.

Reactivity

Hydrolysis and acid-base reactions

Strontium oxide undergoes when exposed to , reacting vigorously to form according to the equation: \text{SrO} + \text{H}_2\text{O} \rightarrow \text{Sr(OH)}_2 This reaction is highly exothermic, releasing significant heat and resulting in a alkaline solution due to the formation of the strong Sr(OH)₂. As a strongly , strontium oxide readily neutralizes acids in proton-transfer reactions, producing the corresponding strontium salts and . For example, it reacts with as follows: \text{SrO} + 2\text{HCl} \rightarrow \text{SrCl}_2 + \text{H}_2\text{O} Such neutralization reactions are employed in the preparation of various strontium salts for industrial applications. In the presence of atmospheric , strontium oxide absorbs CO₂ to form , a process that contributes to its gradual in air: \text{SrO} + \text{CO}_2 \rightarrow \text{SrCO}_3 This carbonation reaction occurs slowly under ambient conditions, particularly when moisture is present to facilitate hydroxide intermediate formation. Although primarily basic, strontium oxide exhibits limited reactivity with strong bases, such as being miscible with fused potassium hydroxide to potentially form mixed hydroxide systems under high-temperature conditions. Aqueous suspensions of strontium oxide achieve a of approximately 13, attributable to the product Sr(OH)₂, which dissociates to provide a high concentration of ions in saturated solutions. The kinetics of are rapid upon direct contact with liquid water, leading to immediate evolution and dissolution, but proceed more slowly with in dry environments, allowing for controlled handling prior to reaction.

Reduction and thermal decomposition

Strontium oxide (SrO) demonstrates exceptional thermal stability, with a boiling point of approximately 3,000 °C, rendering it highly refractory and suitable for high-temperature applications. The reduction of SrO to strontium metal predominantly occurs via aluminothermic processes, exemplified by the reaction $3\text{SrO} + 2\text{Al} \rightarrow 3\text{Sr} + \text{Al}_2\text{O}_3, conducted under vacuum conditions at around 1,200–1,250 °C to promote the vaporization and distillation of the strontium metal. This method, akin to a modified Pidgeon process, utilizes high-purity SrO mixed with aluminum powder, often with additives like barium oxide to enhance slag formation and separation, achieving yields up to 96.9% under optimized conditions of 1–5 mbar pressure and extended reaction times of several hours. The energy barrier for this reduction is overcome by the exothermic nature of the reaction, with activation energies reported around 200–300 kJ/mol in kinetic studies of similar metallothermic extractions. Approximately 90% of global strontium metal production relies on this aluminothermic route due to its efficiency and scalability. Reduction with carbon, via \text{SrO} + \text{C} \rightarrow \text{Sr} + \text{CO}, is theoretically viable but requires temperatures exceeding 1,500 °C and is rarely implemented industrially, as it tends to produce strontium carbide intermediates and yields lower purity metal compared to aluminothermic methods. maintains stability in inert atmospheres at elevated temperatures, showing no significant without a , and as the fully oxidized form of , it exhibits inherent resistance to further oxidation.

Safety and environmental aspects

Health hazards

Strontium oxide is a corrosive substance that causes severe burns to and eyes upon contact, classified under GHS as causing severe skin burns and eye damage (H314). Its reactivity with generates , a strong base that exacerbates caustic effects on tissues. of strontium oxide dust irritates the , potentially leading to symptoms such as coughing and . Chronic exposure may contribute to disruptions in , as the Sr²⁺ mimics Ca²⁺ and accumulates in skeletal tissues, potentially interfering with mineralization processes. Ingestion of strontium oxide results in gastrointestinal irritation, including stomach cramps, , and possible ulceration of the digestive tract. At high doses, it can lead to strontium rickets, a condition characterized by skeletal deformities and impaired development, particularly in juveniles, due to with calcium-dependent bone formation. Compared to other group 2 metal oxides, strontium oxide is less toxic than and considered non-hazardous. Strontium oxide itself is not carcinogenic, with no evidence of or tumor induction from stable forms, though the derivative strontium chromate is a known due to the component.

Environmental considerations

Strontium oxide (SrO) enters the primarily through industrial releases during its production and use in applications such as glass manufacturing and , where thermal processes can emit it as dust or in waste streams. Once released, SrO reacts rapidly with atmospheric moisture to form (Sr(OH)₂), a highly soluble and alkaline compound that can elevate levels in surrounding bodies or if not properly managed. This reactivity contributes to its mobility, as the resulting Sr²⁺ ions dissolve easily and migrate through into , with soil-water coefficients (K_d) ranging from 15 to 496 L/kg, indicating moderate to high mobility depending on and . Safety data sheets emphasize preventing entry into drains or waterways to avoid such dispersion, classifying improper disposal as a potential due to its corrosive nature. In natural settings, stable strontium from SrO persists in soil for decades, with typical concentrations of approximately 200-300 mg/kg, though levels can rise near industrial sites or waste disposal areas like coal ash landfills. It bioaccumulates in ecosystems, particularly in —such as leafy like (up to 74 ppm)—and in the bones of aquatic and terrestrial animals, mimicking calcium and concentrating up to 50,000 times in bones via factors (BCF). However, at environmental exposure levels, stable strontium exhibits low ecotoxicity, with no reported adverse effects on wildlife or ecosystems from typical concentrations in air (∼20 ng/m³), (∼1 mg/L in surface waters), or . Stable strontium compounds are not regulated under standards by the U.S. EPA, unlike radioactive 90Sr. Higher localized releases, such as from or improper , could lead to elevated levels, potentially disrupting skeletal development in juvenile aquatic organisms or causing "" in sensitive at doses exceeding 140 mg/kg/day, though such thresholds are rarely approached in uncontaminated environments. contributions, including from combustion and industrial effluents, have historically increased and burdens, but regulatory frameworks like those from the U.S. EPA treat stable strontium compounds as low-priority pollutants absent . practices recommend containment and disposal in approved facilities to mitigate risks of alkaline or unintended in food chains. Overall, while SrO poses minimal broad-scale environmental threat due to its low inherent toxicity, site-specific monitoring near production facilities is advised to prevent localized impacts on and .

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