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Strontium chloride

Strontium chloride is an with the SrCl₂ and a molecular weight of 158.52 g/mol. It exists as a white, crystalline, odorless solid that is highly soluble in . The compound has a of 874 °C and a of 1250 °C. Strontium chloride serves as a key source of strontium ions in various applications due to its solubility and compatibility with chloride-based systems. In pyrotechnics, it is employed to produce vibrant red flames in and flares by emitting characteristic light when heated. It is also used as a precursor for synthesizing other strontium compounds, in manufacturing, and in metallurgical processes. A notable medical application involves its radioactive isotope, strontium-89 chloride, which is administered intravenously to alleviate in patients with metastatic cancers that have spread to the bones. In dental care, non-radioactive strontium chloride is incorporated into toothpastes to treat dentin by forming a protective barrier over exposed microscopic tubules in teeth. The compound is generally less toxic than analogous but can cause skin, eye, and respiratory irritation upon exposure.

Properties

Physical properties

Strontium chloride is available in both and hexahydrate forms, each exhibiting distinct physical characteristics that influence its handling and applications. The form appears as a white crystalline solid and is odorless. Its is 158.53 g/mol, with a of 3.052 g/cm³. The compound melts at 874 °C and has a of 1,250 °C. It is highly in , with a of 53.8 g/100 mL at 20 °C. The form is hygroscopic, readily absorbing moisture from the air, and remains stable under standard conditions. The hexahydrate form, SrCl₂·6H₂O, manifests as colorless crystals and is also odorless. It possesses a of 266.62 g/mol and a of 1.930 g/cm³ at 20 °C. The hexahydrate dehydrates at 61 °C upon rapid heating, though it can exhibit a higher of around 115 °C under certain conditions. Its solubility in is 106 g/100 mL at 0 °C, increasing to 206 g/100 mL at 40 °C. Like the anhydrous form, the hexahydrate is hygroscopic and effloresces in air, but it maintains stability under standard ambient conditions. The hexahydrate crystallizes in the trigonal system, often forming prismatic habits. Strontium chloride's physical properties, particularly its high water solubility, follow trends observed in analogous alkaline earth metal chlorides like calcium chloride.

Chemical properties

Strontium chloride is a highly ionic compound composed of Sr²⁺ cations and Cl⁻ anions, characteristic of alkaline earth metal chlorides. This ionic bonding results in strong electrostatic interactions, with the larger Sr²⁺ ion exhibiting higher coordination numbers compared to smaller group 2 analogs like Ca²⁺, though lower than Ba²⁺ due to increasing ionic radii down the group. In aqueous solutions, strontium chloride dissociates completely to form neutral solutions with a pH near 7, reflecting minimal hydrolysis as it derives from a strong acid (HCl) and the relatively weak base Sr(OH)₂, unlike more hydrolyzable transition metal chlorides. The compound's chemical properties lie intermediate between those of calcium chloride, which shows lower solubility and reactivity in some contexts, and barium chloride, which displays greater toxicity and solubility trends influenced by the larger barium ion. Strontium maintains a stable +2 oxidation state in the chloride, with no tendency for redox changes under standard conditions, though the chloride ions facilitate electrolytic decomposition to strontium metal and chlorine gas. Thermally, it remains stable up to its melting point of 874°C, beyond which it can volatilize as SrCl₂ gas at the boiling point of 1250°C without immediate decomposition, though further heating may lead to dissociation into elemental strontium and chlorine. Regarding solubility, strontium chloride is highly soluble in , slightly soluble in and acetone, and insoluble in liquid , adhering to general rules for ionic chlorides of group 2 metals. Its solubility in exceeds 50 g/100 mL at , enabling its use in various chemical processes.

Occurrence and Production

Natural occurrence

Strontium is a naturally occurring element in the Earth's crust, with an average abundance of approximately 0.034% by weight, ranking it as the 15th most abundant element. This element is primarily concentrated in two minerals: celestite (SrSO₄), which accounts for the majority of strontium production, and strontianite (SrCO₃), a rarer carbonate form. Celestite is the dominant source, forming in sedimentary deposits through evaporative processes, while strontianite typically occurs in low-temperature hydrothermal veins or limestone cavities. Global strontium resources exceed one billion metric tons, with reserves of about 1.47 million metric tons concentrated primarily in China (1 million tons), Iran (200,000 tons), Spain (40,000 tons), Mexico (20,000 tons), the United States (10,000 tons), and other countries (200,000 tons), as of 2023. Iran leads as the world's largest producer of celestite, followed by Spain, China, and Mexico, which together supply nearly all global output as of 2023. These deposits often form in marine evaporite basins or alkaline igneous environments, where strontium substitutes for calcium in mineral lattices due to their similar ionic radii. For instance, strontianite frequently co-occurs with calcium-bearing minerals, as seen in historical specimens from Strontian, Scotland, where the mineral was first identified and named. Strontium chloride (SrCl₂) does not occur naturally and is entirely synthetic, as strontium halides are rare in geological settings; chloride's high solubility and mobility in aqueous solutions prevent stable mineral formation under typical Earth surface conditions. Instead, strontium cycles through the environment primarily via rock weathering, releasing ions into soils and waters, from which it is taken up by biota. This process enables bioaccumulation in plants, where strontium substitutes for calcium in cellular structures, and in aquatic organisms like shellfish, which incorporate it into their calcium carbonate shells. Such cycling maintains low but persistent environmental levels, influencing ecosystems without forming chloride compounds in situ.

Production methods

Strontium chloride is commonly prepared in laboratories by reacting or with . The reaction with strontium hydroxide proceeds as follows:
\ce{Sr(OH)2 + 2HCl -> SrCl2 + 2H2O}
Similarly, the reaction with strontium carbonate yields:
\ce{SrCO3 + 2HCl -> SrCl2 + CO2 + H2O}
These methods produce an of strontium chloride, which can be crystallized to obtain the solid form. Upon cooling the , strontium chloride typically crystallizes as the hexahydrate, \ce{SrCl2 \cdot 6H2O}, due to its high at decreasing in colder conditions. To obtain the form, the hexahydrate is dehydrated by heating, with occurring in stages starting above 61 °C and completing at approximately 320 °C under controlled conditions to avoid . Industrial production of strontium chloride primarily starts from celestite ore (\ce{SrSO4}), the main natural source of . One common method involves roasting celestite with coke to form strontium sulfide (\ce{SrS}), followed by reaction with :
\ce{SrS + 2HCl -> SrCl2 + H2S}
An alternative direct process leaches crushed celestite with hot concentrated :
\ce{SrSO4 + 2HCl -> SrCl2 + H2SO4}
This approach is efficient for large-scale operations, though it requires handling the byproduct . Purification of strontium chloride involves recrystallization from aqueous solutions to remove impurities like calcium or salts, or vacuum for the anhydrous product to eliminate residual without thermal degradation. These steps ensure high purity for applications requiring it as an intermediate in strontium compound synthesis. Global production of strontium compounds, including strontium chloride as a key intermediate, is derived from approximately 520,000 metric tons of celestite mined annually as of 2023, with major producers being , , , and . Strontium chloride itself accounts for a portion of this, supporting the estimated market value of around USD 380 million in 2025. Strontium chloride was first prepared following the discovery and early of strontium compounds around 1790 from , with early syntheses occurring in the late 18th and early 19th centuries, notably through acid treatments similar to modern methods, prior to Humphry Davy's electrolytic of metallic in 1808 using a strontium chloride mixture.

Structure

Crystal structure

Strontium chloride exists in both and hydrated forms, each exhibiting distinct s determined through and techniques. The form, SrCl₂, adopts the (CaF₂-type) structure, characterized by a face-centered cubic in the Fm-3m (No. 225). In this arrangement, Sr²⁺ cations occupy the corners and face centers of the cubic , while Cl⁻ anions are positioned at the tetrahedral voids, ensuring a three-dimensional ionic framework. Each Sr²⁺ is coordinated to eight Cl⁻ in a cubic , and each Cl⁻ is tetrahedrally coordinated to four Sr²⁺ , reflecting the compound's predominantly character. The parameter a is 6.9744 Å at , as determined experimentally. data confirm the high symmetry and stability of this structure, with bond lengths consistent with strong electrostatic interactions between the . The hexahydrate form, SrCl₂·6H₂O, crystallizes in the trigonal system with P3₂₁ (No. 152). The features infinite chains of [Sr(H₂O)₆]²⁺ octahedra, where each Sr²⁺ is coordinated solely to six oxygen atoms from molecules in a regular octahedral , with isolated Cl⁻ anions residing between these cationic chains to maintain charge balance. parameters are a = 7.9596 and c = 4.1243 . studies reveal precise positions and a network of bonds that stabilize the framework, underscoring the role of molecules in the coordination environment and overall ionic assembly.

Vapor phase structure

In the vapor phase, strontium chloride exists primarily as discrete SrCl₂ s that exhibit a geometry, characterized by a thermal average Cl–Sr–Cl bond angle of 142.4° ± 4.0° and an Sr–Cl of 2.625 ± 0.010 (r_g structure). This configuration arises from a shallow bending , with quantum-chemical calculations at the level indicating a small barrier of approximately 0.1 kcal mol⁻¹ at the linear geometry, leading to vibrational averaging that results in the observed non-linearity. Although valence shell electron pair repulsion ( predicts a linear for this AX₂-type , the nature reflects polarization effects and the weak in the gas phase, where the structure is more molecular than in the solid state lattice. The molecular parameters were experimentally determined through high-temperature gas-phase , complemented by computations that yield an equilibrium Sr–Cl of 2.605 ± 0.006 , in close agreement with the thermal average. Supporting evidence comes from gas-phase , which has identified vibrational modes consistent with the bent structure, including asymmetric and symmetric stretching frequencies that align with the computed constants. Matrix-isolated studies further corroborate these findings, though they may show slight perturbations due to interactions with the host matrix. At lower vapor pressures or temperatures, SrCl₂ tends to dimerize, forming (SrCl₂)₂ with two bridging ligands in a planar, rhombic arrangement around each strontium center, though monomers predominate under typical high-temperature conditions. This gas-phase molecular behavior is particularly relevant in high-temperature processes, such as during or in flames, where the quasilinear monomers influence spectroscopic signatures and reactivity.

Applications

Pyrotechnics

Strontium chloride has been employed in pyrotechnics since the 19th century to produce vibrant red colors in fireworks, particularly for red stars, due to the introduction of stronger oxidizers like potassium chlorate that enabled more intense flame emissions. This compound contributes to the crimson hues observed in displays by facilitating the formation of excited strontium species during combustion. The arises from electronic transitions in ions, primarily through the molecular of strontium monochloride (SrCl), which produces a bright at wavelengths of 635 , 660 , and 672 . In contrast, other strontium salts like the lead to emissions from SrO at around 606 (orange-) or SrOH in the 630–700 range (less saturated ), making SrCl superior for deeper, more vivid tones. The overall spans 606–686 , enhanced by the presence of , which suppresses unwanted orange contributions from or species. In pyrotechnic formulations, strontium chloride is preferred for its and is mixed with oxidizers such as (KNO₃) and fuels like or chlorinated organics to achieve a balanced oxygen supply and chlorine donation for optimal SrCl formation. This approach yields a cleaner burn compared to strontium alone, as the chloride reduces hygroscopic issues and minimizes extraneous emissions, resulting in higher color purity without the water absorption problems associated with nitrates. Specific applications of strontium compounds include road flares for emergency signaling, tracer bullets in to mark trajectories with a visible trail, and distress signals for high-visibility alerts at sea.

Dental care

Strontium chloride has been utilized in oral health products primarily as a desensitizing agent to alleviate dentin , a common condition causing sharp pain in teeth exposed to , tactile, or chemical stimuli. This application leverages the compound's ability to interact with tooth surfaces, providing relief for individuals with sensitive teeth resulting from erosion or . The mechanism of action involves strontium ions from strontium chloride reacting with carbonate ions present in saliva to form (SrCO₃) precipitates. These precipitates deposit within the dentinal tubules, occluding them and blocking the flow of fluids that trigger pain according to the hydrodynamic theory of , thereby reducing discomfort from hot, cold, or other irritants. The incorporation of strontium chloride into dental formulations originated from in the mid-20th century, with filed in the late 1950s and early for its desensitizing and potential anti-cavity properties, marking an early in over-the-counter oral care. Commercially, strontium chloride was introduced in toothpastes such as Original in the , where it was formulated at approximately 10% strontium chloride hexahydrate to effectively target . In terms of efficacy, clinical studies have demonstrated that regular use of strontium chloride-containing dentifrices results in significant reductions in , with reported decreases in scores ranging from 40% to 60% after consistent application over several weeks; the U.S. has approved such formulations as desensitizing agents. Unlike potassium nitrate-based desensitizers, which work by depolarizing endings to temporarily block signals, strontium chloride primarily achieves relief through physical of dentinal tubules rather than neural modulation. The hexahydrate form of strontium chloride is commonly employed in dental gels and aqueous pastes due to its stability and solubility in , facilitating effective delivery to surfaces without compromising product consistency.

Biological research

Strontium chloride (SrCl₂) is widely employed in to induce parthenogenetic of mammalian , a process that mimics the triggered by natural fertilization. At concentrations of 10 mM, SrCl₂ effectively activates cumulus-free , achieving activation rates of up to 91% after exposure durations of 0.5 to 5 hours. In human and bovine models, similar concentrations (10-20 mM) have been used successfully to promote oocyte in fertilization (IVF) and experiments. The mechanism involves Sr²⁺ ions entering the through plasma membrane channels, such as TRPV3, where they substitute for Ca²⁺ due to their similar ionic properties and trigger repetitive calcium oscillations via inositol 1,4,5-trisphosphate (InsP₃) receptor-mediated release from intracellular stores. These oscillations activate downstream pathways essential for meiotic resumption, cortical granule , and pronuclear formation, facilitating production in assisted reproduction protocols. In practice, oocytes are typically incubated in SrCl₂ medium for 4-6 hours post-IVF or (ICSI), often combined with 5 μg/mL cytochalasin B to inhibit extrusion and enhance diploidy. Activation success rates approximate 70% across , , and bovine systems, with improved fertilization outcomes in cases of ICSI failure. Compared to calcium ionophores like A23187, which induce transient Ca²⁺ rises, SrCl₂ produces longer-lasting oscillations that more closely resemble physiological sperm-induced patterns, potentially supporting better embryonic development in animal models. This application of SrCl₂ originated in the as part of advancements in ICSI and parthenogenetic techniques, with early studies demonstrating its efficacy in oocytes for and IVF research.

Industrial uses

Strontium chloride serves as a key precursor in the industrial synthesis of various strontium salts through reactions. For instance, it is reacted with sodium chromate to produce strontium chromate (SrCrO₄), a employed as a in protective coatings for metals like aluminum. Similarly, with yields (SrCO₃), which is widely used in the ceramics to formulate glazes and ferrites due to its fluxing properties and ability to enhance durability: \text{SrCl}_2 + \text{Na}_2\text{CO}_3 \rightarrow \text{SrCO}_3 + 2\text{NaCl} In the oil and gas sector, strontium chloride is converted to strontium sulfate (SrSO₄) via reaction with sodium sulfate, serving as a weighting agent in drilling fluids to control formation pressure and prevent blowouts. Another significant industrial application involves strontium chloride's role in ammonia storage systems for selective catalytic reduction (SCR) of nitrogen oxides (NOx) in diesel engine exhaust. It forms reversible ammine complexes, such as [Sr(NH₃)₈]Cl₂, which absorb and release ammonia efficiently under varying temperatures, enabling compact solid-state storage that improves NOx conversion efficiency, particularly at low exhaust temperatures below 200°C. These complexes outperform traditional urea-based systems by reducing ammonia slip and enhancing system reliability in heavy-duty vehicles. In , strontium chloride combined with (typically 0.02 M SrCl₂ and 0.05 M ) acts as an extractant in testing to assess nutrient availability. This method effectively solubilizes exchangeable forms of , , and other micronutrients like , providing a reliable indicator of and guiding applications without interfering with calcium or magnesium extraction. Studies have validated its efficacy across diverse types, including soils, where it correlates well with plant uptake. Strontium chloride finds minor applications in electron tubes as a component in vacuum systems and getters, and in optical experiments for due to its distinct emission lines. Additionally, it plays a limited role in the electrolytic production of strontium metal, where molten strontium chloride mixed with undergoes in a , yielding pure at the while gas evolves at the . Market analyses indicate that strontium chloride constitutes a notable portion of strontium compound intermediates, supporting these downstream processes. As of 2025, strontium chloride is being investigated for thermochemical applications, utilizing its hydration and dehydration cycles to store and release efficiently in low-temperature systems. Recent studies have examined its structural and morphological transformations during , highlighting its potential for solutions.

Safety and Environmental Impact

Health hazards

Strontium chloride is an irritant to the eyes and upon acute exposure. Contact with the eyes can cause serious damage and severe requiring immediate medical attention. Skin exposure does not cause significant based on standardized tests, though general irritant classifications apply. of dust or fumes irritates the , leading to coughing, , and mucosal . Ingestion of strontium chloride exhibits low acute oral toxicity, with an LD50 greater than 2,000 mg/kg in rats, indicating it is not highly poisonous in single doses. However, it can cause gastrointestinal disturbances such as , , , and due to its similarity to calcium in metabolic pathways. Unlike more toxic analogs like , strontium chloride does not typically lead to severe systemic effects from incidental ingestion. Chronic inhalation or ingestion may pose risks, particularly to bone health, as strontium mimics calcium and accumulates in skeletal tissue. Prolonged exposure has been associated with in children, characterized by impaired bone development and growth disturbances, especially in cases of nutritional deficiencies. No evidence links strontium chloride to carcinogenicity; it is not classified as a by major regulatory bodies. Regulatory classifications identify strontium chloride as an irritant () under older directives, with hazards including eye damage and respiratory irritation. OSHA has not established a specific (PEL) for strontium compounds, but general limits for dust apply at 15 mg/m³ (total) and 5 mg/m³ (respirable) as an 8-hour time-weighted average. Children and pregnant women are vulnerable populations due to strontium's interference with calcium-dependent and higher rates during phases.

Environmental considerations

Strontium chloride is highly soluble in , with a solubility of 53.8 g/100 mL at 20°C for the form, facilitating rapid dispersion and limiting long-term persistence in environments. Once released, the compound dissociates into Sr²⁺ ions, which exhibit moderate mobility in soils and sediments due to to clays and metal oxides, but in bodies, natural dilution occurs effectively in large volumes. The Sr²⁺ ion can bioaccumulate in organisms, particularly in and , where factors (BCF) relative to levels can exceed 50,000 in bony tissues in soft, low-calcium waters due to its to calcium. Ecotoxicity of strontium chloride to life is generally low, with thresholds such as LC50 values exceeding 100 mg/L for like (Morone saxatilis) over 96 hours. Chronic effects are minimal at environmentally relevant concentrations, and the compound poses no risk of or contribution to , as it is neither volatile nor a . Primary sources of strontium release into the environment from anthropogenic activities include industrial effluents during strontium chloride production and runoff from mining operations extracting celestine (SrSO4), the principal ore for strontium compounds. These releases can elevate local strontium levels in surface waters and soils near production sites. Under the European Union's REACH regulation, strontium chloride (CAS 10476-85-4) is registered, requiring assessment of environmental risks, though it is not classified as a persistent, bioaccumulative, or toxic (PBT) substance. In the United States, the Environmental Protection Agency (EPA) does not list stable strontium as a priority pollutant under the Clean Water Act, but it monitors radioactive isotopes in drinking water with a maximum contaminant level (MCL) equivalent to 4 mrem/year whole-body or organ dose, primarily targeting strontium-90 rather than stable forms. Stable strontium lacks a federal MCL for non-radioactive exposure. Remediation efforts for strontium chloride releases are rarely necessary, as its high promotes natural attenuation through dilution in rivers, lakes, and oceans, where background concentrations (e.g., 0.001–13.6 mg/L in freshwater) often mask low-level inputs. In the long term, elevated from repeated industrial or mining inputs can contribute to increased levels, potentially interfering with calcium uptake in crops and affecting if concentrations exceed natural baselines (e.g., >240 mg/kg globally).