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Strontium carbonate

Strontium carbonate is the inorganic compound with the chemical formula SrCO₃, appearing as a white, odorless, crystalline powder that is sparingly soluble in water but reacts with acids to release carbon dioxide. It has a molecular weight of 147.629 g/mol, a density of 3.5 g/cm³, and decomposes upon heating above 1200°C into strontium oxide and carbon dioxide, without a distinct melting point. Strontium carbonate was first identified in 1790 from the mineral discovered in , . In nature, it occurs as the mineral , though it is less abundant than celestite (strontium , SrSO₄), which serves as the primary commercial source of . Strontium constitutes about 0.038% (384 ) of the , and as of 2023, is extracted mainly from celestite deposits in countries including , , , and . It is industrially produced from celestite, primarily via the black ash process. Strontium carbonate is widely used in ceramics, , , and as a precursor for other strontium compounds. It has low but can cause mild irritation upon exposure.

Overview

Chemical identity and natural occurrence

Strontium carbonate is an with the SrCO₃ and a of 147.63 g/mol. It appears as a white to grey powder in its pure form. Naturally, it occurs as the mineral , which is the primary strontium-bearing . Strontianite crystallizes in the orthorhombic system, with symmetry 2/m 2/m 2/m, forming short to long prismatic, acicular, or pseudohexagonal crystals that can reach up to 8 cm in length. Its is analogous to that of , featuring slightly larger cell parameters due to the larger . The exhibits a vitreous to resinous luster and is brittle, with nearly perfect cleavage on {110}. Strontianite is a rare mineral, named after its type locality in , , , where it was first identified in lead mines around 1791. Significant deposits also occur in association with celestine (strontium sulfate) worldwide, including in the Mud Hills near , within Miocene sedimentary layers of the Barstow formation, and in low-temperature hydrothermal veins in limestone and marl in regions like , . Other notable sites include the in and various locations in the United States such as . Geologically, strontianite forms through low-temperature hydrothermal processes in veins, geodes, and concretions within carbonate-rich sedimentary environments like , , and , or as a mineral in metallic sulfide veins; it is also common in carbonatites. It often associates with minerals such as , barite, celestine, and sulfur, precipitating under conditions favoring strontium carbonate stability in these settings.

History

Strontium was first identified in 1790 by Scottish chemists Adair Crawford and William Cruickshank, who analyzed samples of the mineral (SrCO₃) obtained from lead mines near the village of in Argyllshire, . The and its compounds were named after this locality, derived from the "Sròn an t-Sìthein," meaning "nose of the fairy hill." In the early 19th century, German chemist conducted detailed analyses of , confirming in 1793 that it was chemically distinct from (barium sulfate) and (barium carbonate), thus establishing strontium as a unique alkaline earth element. Building on this, isolated strontium metal for the first time in 1808 through of a mixture of and mercuric oxide at the Royal Institution in . During the 1800s, strontium carbonate found initial applications in for producing brilliant red colors in and in glassmaking to refine optical clarity and color. Commercial production of strontium carbonate began in the mid-19th century, primarily from celestine (SrSO₄) deposits, with early operations in starting around to meet growing demand for these uses. A key advancement came in the early with the development of the black ash process, which improved efficiency by roasting celestine with to form strontium sulfide, followed by to yield high-purity strontium carbonate.

Properties

Physical properties

Strontium carbonate is a white, odorless powder that may appear greyish-white depending on purity and preparation method. The compound has a of 3.5 g/cm³. It does not melt but decomposes without melting above approximately 1200 °C into and , with decomposition onset around 875 °C depending on conditions. Strontium carbonate is practically insoluble in , with solubility reported as low as 0.0011 g/100 mL at 18 °C, though literature values vary up to 0.011 g/100 mL at similar temperatures, highlighting discrepancies possibly due to measurement conditions or sample variations. Solubility increases substantially to approximately 0.1 g/100 mL in saturated with , owing to the formation of the more soluble strontium . Additional physical characteristics include a refractive index of 1.518 and thermal stability maintained up to approximately 1200 °C, beyond which it decomposes without prior phase change.

Chemical properties

Strontium carbonate (SrCO₃) is an ionic compound composed of the divalent strontium cation (Sr²⁺) and the carbonate anion (CO₃²⁻), forming a lattice with an orthorhombic crystal structure akin to the mineral aragonite. The carbonate ion imparts basic character to the compound through hydrolysis in aqueous environments, where CO₃²⁻ reacts with water to produce bicarbonate and hydroxide ions (CO₃²⁻ + H₂O ⇌ HCO₃⁻ + OH⁻), resulting in a weakly basic solution with a pH of approximately 7-8 for dilute suspensions. In terms of reactivity, strontium carbonate dissolves readily in acids, liberating gas and forming soluble strontium salts. A representative reaction with is given by the equation: \text{SrCO}_3 + 2\text{HCl} \rightarrow \text{SrCl}_2 + \text{H}_2\text{O} + \text{CO}_2 This acid-base reaction proceeds via of the ion, leading to characteristic of metal carbonates. The compound exhibits thermal instability at elevated temperatures, decomposing above 1,200 °C to yield and according to: \text{SrCO}_3 \rightarrow \text{SrO} + \text{CO}_2 Decomposition initiates around 875 °C under certain conditions but requires higher temperatures for complete conversion, influenced by factors such as and atmosphere. Strontium carbonate demonstrates good under ambient conditions, remaining resistant to atmospheric moisture and non-hygroscopic, which allows safe handling without significant degradation. For identification purposes, its spectroscopic properties are distinctive; () spectroscopy shows characteristic absorption bands for the group, including the out-of-plane mode (ν₂) at about 854 cm⁻¹, asymmetric (ν₃) around 1,400-1,500 cm⁻¹, and symmetric (ν₁) near 1,040-1,105 cm⁻¹, confirming its aragonite-like structure.

Production

Natural sources and extraction

Strontianite (SrCO₃) serves as the primary mineral for natural strontium carbonate, but it is considerably rarer than celestite (SrSO₄), the dominant strontium-bearing mineral that accounts for the vast majority of commercial production. Strontianite typically forms as a low-temperature hydrothermal mineral or groundwater precipitate in carbonate sedimentary rocks, such as , and is occasionally associated with formations. Significant global deposits of strontianite occur in at the locality, where the mineral was first identified in 1790 during lead operations; in , ; near Barstow in , , within the Mud Hills; and in , where a developed deposit has been noted as the primary active source. These sites represent the key geological sources, though strontianite's overall scarcity limits its contribution to less than 1% of global resources. Extraction of begins with the using open-pit methods for shallow, unconsolidated deposits or underground techniques for deeper veins, as demonstrated in early 20th-century operations at the sites where loose clays necessitated surface gathering of high-grade float material. The mined undergoes crushing and grinding to liberate the mineral, followed by to separate strontianite from minerals like and silica, yielding a concentrate with high purity—often exceeding 87% SrCO₃ in premium deposits. may be applied selectively to remove volatile impurities, further refining the product without altering the carbonate form. Direct extraction from strontianite provides high-purity strontium carbonate suitable for specialized applications, but its limited availability constrains yields and economic viability. Strontianite mining has declined significantly since the 1950s, particularly in the United States where no production has occurred since 1959, due to the preference for processing the more abundant celestite into strontium compounds via industrial methods.

Industrial preparation

The primary industrial method for producing strontium carbonate is the black ash process, which starts with celestite (SrSO₄) as the main precursor. In this process, finely ground celestite is roasted with coke in a rotary kiln at temperatures of 1,100–1,300 °C to reduce it to strontium sulfide according to the reaction: \text{SrSO}_4 + 2\text{C} \rightarrow \text{SrS} + 2\text{CO}_2 The resulting strontium sulfide is then leached with hot water and oxidized using carbon dioxide and water to precipitate strontium carbonate, yielding hydrogen sulfide as a byproduct via the reaction: \text{SrS} + \text{CO}_2 + \text{H}_2\text{O} \rightarrow \text{SrCO}_3 + \text{H}_2\text{S} The hydrogen sulfide byproduct is captured and managed through scrubbing to prevent environmental release. An alternative approach is the direct conversion process, where celestite is treated with a sodium carbonate (Na₂CO₃) solution under steam conditions to form crude strontium carbonate and sodium sulfate. The crude product is subsequently purified by acidification with hydrochloric acid (HCl) to solubilize impurities, followed by re-precipitation using CO₂ or Na₂CO₃ to obtain higher-purity strontium carbonate. Another synthetic route involves double decomposition, in which (SrCl₂), derived from the reaction of celestite with HCl, is reacted with solution: \text{SrCl}_2 + \text{Na}_2\text{CO}_3 \rightarrow \text{SrCO}_3 + 2\text{NaCl} This method is particularly useful for producing high-purity grades suitable for specialized applications. As of 2023, global celestite production, the main precursor for strontium carbonate, was 520,000 metric tons, with major producers including , , (80,000 tons, or 15%), and (200,000 tons). In 2023, produced 200,000 metric tons of celestite, emerging as a key supplier. Global resources exceed 1 billion metric tons, primarily as celestite. These processes typically achieve 98–99% purity for the final product, with impurities and byproducts like or handled through and scrubbing steps to meet commercial standards.

Microbial precipitation

Microbial precipitation of strontium carbonate involves biological processes where microorganisms, particularly cyanobacteria, facilitate the formation of strontium-bearing carbonate minerals through biomineralization. In natural settings, epilithic cyanobacteria such as Calothrix, Synechococcus, and Gloeocapsa induce precipitation by serving as nucleation sites and elevating local pH via photosynthetic uptake of CO₂, which promotes the exchange of HCO₃⁻ for OH⁻ and leads to the supersaturation of carbonate ions with strontium and calcium ions present in the environment. This results in the formation of strontian calcite, a solid solution where strontium substitutes for calcium in the calcite lattice, typically incorporating up to 1 wt% Sr due to the similar chemical behavior of Sr²⁺ and Ca²⁺ despite their ionic radius differences. Such precipitation occurs in diverse environments, including discharge zones associated with bedrock, alkaline lakes, and soils, as well as controlled lab-scale bioreactors. In these settings, the process forms porous thrombolitic crusts or intracellular and extracellular phases, often as (Sr,Ca)CO₃ solid solutions, with like Synechocystis sp. PCC6803 and Pseudanabaena catenata demonstrating the ability to stabilize amorphous carbonates before crystallizing into (SrCO₃) or mixed phases under varying ionic conditions. Early research in the 1990s highlighted the role of cyanobacterial in strontium calcite formation at specific sites, establishing photosynthesis-driven pH shifts as a key mechanism. Post-2020 advances have leveraged and targeted culturing to enhance production; for instance, studies on Synechocystis sp. PCC6803 showed prolonged stabilization of strontium-rich amorphous carbonates in SrCl₂-amended media, while Pseudanabaena catenata achieved near-complete Sr removal under alkaline (~11.4), forming both extracellular and intracellular strontium polyphosphates. Additionally, ureolytic and like Gloeomargarita lithophora have been explored for intracellular CaCO₃ formation that sequesters Sr, building on these foundational mechanisms for more efficient . This biological approach holds potential for , particularly in removing from , including contaminated industrial effluents. Laboratory studies using indigenous ureolytic have demonstrated up to 94% Sr precipitation efficiency over 25 days through , which generates and incorporates Sr into or phases, offering a low-energy alternative for treating strontium-laden waters. Compared to precipitation, strontium incorporation is limited by the larger of Sr²⁺ (1.18 Å) versus Ca²⁺ (1.00 Å), which hinders extensive substitution and favors formation of distinct phases or low-Sr solid solutions rather than pure SrCO₃ at higher concentrations. This mismatch also extends the amorphous phase duration in cyanobacterial biofilms, as observed in Sr-amended cultures where extracellular polymeric substances adapt to stabilize precursors before .

Applications

Pyrotechnics and ceramics

Strontium carbonate is widely employed in as a colorant to produce a crimson-red color in and flares, resulting from the excitation of Sr²⁺ ions that emit at wavelengths between 606 and 686 . This compound is preferred over in such formulations due to its non-hygroscopic nature, which prevents moisture absorption and ensures composition stability, as well as its lower cost. In pyrotechnic mixtures, it typically constitutes 1-5% of the formulation to achieve optimal color intensity while acting as an acid neutralizer to enhance burning efficiency. Historically, strontium carbonate has been used in pyrotechnics since the 19th century for signal flares and tracers, where its red emission provided clear visual signaling in marine and military applications. This early adoption leveraged the compound's ability to yield a brilliant red upon combustion, making it suitable for railroad fusees and emergency signals. In ceramics, strontium carbonate serves as a flux that lowers the melting point of glazes and enamels, promoting fusibility and producing glossy, craze-resistant surfaces by introducing strontium oxide (SrO) into the formulation. It is also a key precursor in the production of strontium ferrites, such as SrFe₁₂O₁₉, which are synthesized by reacting strontium carbonate with iron oxide to form high-performance permanent magnets valued for their magnetic stability. Additional applications include the manufacture of iridescent glass for radiation-resistant components and luminous paints, where dosages of 1-5% contribute to enhanced optical effects. Compared to barium carbonate alternatives, strontium carbonate offers advantages in ceramics and pyrotechnics, including lower toxicity, reducing health risks during handling and processing.

Electronics and other uses

Strontium carbonate serves as a key precursor in the production of strontium ferrites, which are widely used in permanent magnets for electronic devices such as motors, speakers, and generators. These magnets are synthesized by calcining a mixture of strontium carbonate and iron oxide to form the ferrite phase, offering cost-effective magnetic properties suitable for high-volume applications. In advanced electronics, strontium carbonate is employed in the synthesis of high-temperature superconductors like (BSCCO), where it provides the strontium component through solid-state reactions with other metal oxides and carbonates. BSCCO materials, with critical temperatures above 77 K, are used in applications requiring zero electrical resistance, such as and . Additionally, strontium carbonate is calcined to for incorporation into electroluminescent materials, including doped (SrS) phosphors that emit light under , historically applied in thin-film displays for vibrant . Strontium carbonate finds use in cathode ray tube (CRT) glass for color televisions, where it absorbs and X-rays emitted from the , enhancing safety and image quality. It also acts as a precursor for (SrTiO₃), produced via solid-state reaction with , which serves as an optical material in capacitors, substrates, and layers due to its high and transparency. In refining processes, strontium carbonate precipitates impurities as strontium salts, aiding the purification of by removing excess and certain drugs by isolating organic contaminants. Recent developments in the 2020s have explored doping in solar cells to improve and ; for instance, incorporating into tin-based perovskites reduces self-p-doping and structural defects, boosting power conversion from 6.3% to 7.5%.

Safety and environmental considerations

Health effects

Strontium carbonate exhibits low , with an oral LD50 greater than 2,000 mg/kg in rats, indicating minimal risk from single high-dose ingestion. It acts as an irritant to the skin, eyes, and , particularly upon of dust, potentially causing redness, discomfort, or in exposed tissues. As a non-essential element, (Sr²⁺) biologically mimics calcium (Ca²⁺), leading to its preferential accumulation in and teeth, where approximately 99% of absorbed strontium is deposited. This substitution can disrupt normal bone mineralization over time, with a in human of about 30 years, resulting in long-term retention. Chronic exposure to elevated levels of stable strontium has been associated with rickets-like effects in children, including impaired cartilage and bone softening, as well as in adults. Human exposure to strontium carbonate primarily occurs through of fine dust particles during mining, processing, or handling, which can lead to respiratory irritation. Ingestion represents another key route, often via contaminated with naturally occurring , for which the U.S. Environmental Protection Agency has established a lifetime advisory level of 4 mg/L to protect against potential bone-related risks. Although strontium carbonate is chemically stable and non-radioactive in its typical form, trace amounts of the radioactive (from or environmental sources) may be present in some natural deposits, potentially contributing to long-term if accumulated in . Recent safety data sheets classify strontium carbonate as non-hazardous for transport under standard conditions, with no specific radioactive hazards noted for commercial grades. No specific OSHA exists for strontium compounds; general limits for respirable dust (5 mg/m³) and total dust (15 mg/m³) apply to minimize risks in settings.

Ecological impact

The extraction of strontium carbonate precursors, such as celestite (SrSO₄) and (SrCO₃), primarily occurs in major producing regions like , , , and . As of , global production of (in celestite) totaled approximately 520,000 metric tons, with and each accounting for about 38%, 15%, and 7%. operations in these areas have led to significant habitat disruption, including and in arid ecosystems. In , a significant producer and exporter of strontium compounds (accounting for about 43% of U.S. imports as of ), mining activities contribute to land clearance and deposition, potentially affecting local ecosystems. Similarly, in , extraction contributes to broader amid intensive mineral resource development. from these operations releases into nearby waterways, as oxidation generates acidic runoff that mobilizes Sr²⁺ ions, potentially elevating downstream concentrations and altering aquatic chemistry. Industrial effluents from strontium carbonate processing represent a key release pathway, with discharged wastewater often containing strontium concentrations reaching several milligrams per liter, depending on production scale and treatment efficacy. These releases can lead to bioaccumulation of strontium in aquatic organisms, particularly in the skeletal structures of fish such as otoliths, scales, and bones, where Sr²⁺ substitutes for calcium due to chemical similarity, potentially disrupting calcium homeostasis at elevated exposure levels. The persistence of strontium carbonate in the is influenced by its low , which generally limits mobility in neutral or alkaline and reduces immediate risks. However, in acidic —common in regions affected by or atmospheric deposition—dissolution as strontium bicarbonate increases , facilitating uptake by and soil in calcium-deficient conditions. Under the European Union's REACH regulation, strontium carbonate was registered in the , mandating environmental risk assessments and monitoring to evaluate releases into and compartments during and use. In the 2020s, strontium isotopes have been increasingly utilized as tracers in studies to track inputs, such as from industrial effluents or mine drainage, aiding in the identification of contamination sources in and surface waters. Mitigation strategies include via microbial precipitation, where ureolytic induce strontium carbonate formation in , effectively sequestering Sr²⁺ with removal efficiencies exceeding 90% under optimized conditions like controlled Sr/Ca ratios. This approach leverages indigenous microbes in sediments to generate and precipitate stable minerals, offering a sustainable alternative to chemical treatments for strontium-laden effluents from and sites.

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