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Sodium molybdate

Sodium molybdate is an with the Na₂MoO₄, consisting of two sodium cations and one anion, typically appearing as a white, crystalline powder that is highly soluble in (84 g/100 mL at 100°C). It has a molecular weight of 205.93 g/, a of 3.78 g/cm³, and a of 687°C. Commercially, sodium molybdate is often produced as the dihydrate (Na₂MoO₄·2H₂O), which forms colorless crystals and serves as a key source of in various applications. The compound is industrially synthesized by reacting (MoO₃) with (NaOH) in an , followed by , often yielding the dihydrate form under ambient conditions. In the United States, annual volumes ranged from 1,000,000 to less than 10,000,000 pounds from 2016 to 2019, reflecting its importance as a molybdenum . Sodium molybdate finds widespread use as a in industrial cooling systems and metal finishing processes due to its non-oxidizing anodic properties, which help prevent pitting and scaling without promoting microbial growth. It also serves as a in fertilizers to address deficiencies in crops, enhancing in , and as an additive in pigments, dyes, and pesticides. In , it acts as a reagent for detecting alkaloids and phosphates, while in , it functions as an additive for capacitors and batteries to improve performance and stability. Despite its utility, sodium molybdate is classified as or inhaled, with an oral LD50 of approximately 4000 / in rats, and it can cause and eye irritation upon contact. Prolonged exposure may affect the , necessitating proper handling in industrial settings.

Properties

Physical properties

Sodium molybdate exists in and hydrated forms, with the Na₂MoO₄ for the variant and Na₂MoO₄·2H₂O for the common dihydrate. The is 205.93 g/mol for the form and 241.95 g/mol for the dihydrate. In its solid state, sodium molybdate appears as a white crystalline powder or colorless crystals, and it is odorless. The form has a of 3.78 g/cm³ at 25 °C. It melts at 687 °C and decomposes at higher temperatures without reaching a . The compound exhibits high in , with approximately 65 g dissolving per 100 mL at 25 °C for the form, increasing to 84 g per 100 mL at 100 °C; the dihydrate form has a of about 76 g/100 mL at 25 °C. The dihydrate loses upon heating, dehydrating around 100 °C.
Property (Na₂MoO₄)Dihydrate (Na₂MoO₄·2H₂O)
(g/mol)205.93241.95
(g/cm³)3.78 (25 °C)~2.37 (bulk, 25 °C)
(°C)687100 ()
in 84 g/100 mL (100 °C)76 g/100 mL (25 °C)

Chemical properties

Sodium molybdate is an ionic compound consisting of sodium cations (Na⁺) and anions (MoO₄²⁻). In aqueous solutions, the undergoes , imparting slight basicity to the solution, with values typically ranging from 7.0 to 10.5 for 5% solutions and around 8.0 to 10.0 for more concentrated solutions up to 35%. The form exhibits high thermal stability, remaining intact up to its of 687 °C, while the dihydrate loses its upon heating to approximately 100 °C, forming the . Molybdenum in sodium molybdate is in the +6 , the highest for the element, rendering it resistant to further oxidation under standard conditions. The compound is highly soluble in and alkaline solutions but shows limited in acidic media, where it tends to react rather than dissolve intact, forming protonated .

Structure

Molecular structure

Sodium molybdate consists of sodium cations and the anion, [MoO₄]²⁻, where the central molybdenum(VI) atom is coordinated to four oxygen atoms in a tetrahedral with Td . This arrangement features Mo–O bond lengths of approximately 178 pm, as determined in aqueous solutions via large-angle . In solution, the compound dissociates into Na⁺ ions and the intact [MoO₄]²⁻ anions, with no direct covalent Na–O bonding; the sodium ions are solvated by molecules independently of the molybdate . The molecular structure is characterized by spectroscopic signatures that confirm the tetrahedral coordination. Infrared (IR) spectroscopy reveals characteristic Mo–O stretching vibrations, including the symmetric stretching mode (ν₁) around 950 cm⁻¹ and asymmetric modes (ν₃) in the 800–900 cm⁻¹ range, though the exact positions can vary slightly due to site symmetry distortions in the solid state. Ultraviolet-visible (UV-Vis) spectroscopy shows intense absorption bands below 300 nm, attributed to ligand-to-metal charge transfer transitions from oxygen 2p orbitals to molybdenum 4d orbitals. In the common dihydrate form, Na₂MoO₄·2H₂O, the water molecules primarily coordinate to the sodium cations, forming hydrogen-bonded networks that link the [MoO₄]²⁻ anions without significantly perturbing the core tetrahedral geometry of the molybdate ion. This loose hydration shell maintains the isolated nature of the [MoO₄]²⁻ unit, consistent with its behavior in aqueous environments.

Crystalline forms

Sodium molybdate exhibits multiple crystalline forms, primarily distinguished by their hydration states, each with distinct lattice parameters and packing arrangements. The anhydrous form, Na₂MoO₄, crystallizes in the cubic system with space group Fd¯3m, adopting a spinel structure where Na⁺ ions occupy octahedral coordination sites (16c Wyckoff positions) and Mo⁶⁺ ions reside in tetrahedral sites (8b positions), resulting in a close-packed ionic lattice without water molecules. The dihydrate, Na₂MoO₄·2H₂O, the most commonly encountered phase at room temperature, forms in the orthorhombic crystal system with space group Pbca (unit cell parameters a ≈ 8.46 Å, b ≈ 10.55 Å, c ≈ 13.83 Å, Z = 8); its structure consists of alternating layers of tetrahedral MoO₄²⁻ anions and water molecules, linked by Na⁺ cations in irregular polyhedra (NaO₅ and NaO₆) and hydrogen bonds from the coordinated water molecules that bridge between Na⁺ and MoO₄²⁻ units. A decahydrate , Na₂MoO₄·10H₂O, crystallizes at low temperatures below approximately 283 and features a more loosely packed arrangement with an extensive shell, where multiple molecules form a complex hydrogen-bonding network around the isolated tetrahedral MoO₄²⁻ cores and Na⁺ ions. These forms exist in - and humidity-dependent ; the decahydrate converts to the dihydrate upon mild heating or increased , while the dihydrate dehydrates to the form through stepwise loss starting around 100°C, often via intermediate lower hydrates under controlled conditions.

Preparation

Laboratory synthesis

Sodium molybdate is commonly synthesized in the laboratory by dissolving (MoO₃) in an of (NaOH) at temperatures ranging from 50 to 70 °C. This forms the soluble sodium molybdate, which can then be isolated through cooling and . The simplified for the process is: \ce{MoO3 + 2 NaOH -> Na2MoO4 + H2O} In aqueous conditions, the product typically crystallizes as the dihydrate (Na₂MoO₄·2H₂O). After dissolution, the hot solution is filtered to remove insoluble residues, then allowed to cool slowly to promote the formation of colorless, orthorhombic crystals of the dihydrate. The crystals are separated by , washed with cold water, and dried under or at low temperature to prevent further changes. This bench-scale procedure is efficient for producing small quantities (grams to tens of grams) suitable for analytical or experimental use. The NaOH-based synthesis generally achieves yields exceeding 90%, with the product's purity enhanced to over 99% through recrystallization from hot water, where less soluble impurities are excluded. Further purification can involve ion-exchange or additional recrystallizations if trace metals are present. To prepare the form, the dihydrate crystals are gently heated at 100 °C under reduced , driving off the waters of without .

Industrial production

Sodium molybdate is produced on an industrial scale primarily from (MoS₂) ore, the main source of , through a multi-step process involving and alkaline treatment. concentrate, often obtained as a of , is roasted in air at temperatures around 500–700°C to convert MoS₂ to (MoO₃), with (SO₂) released as a that is typically captured and converted to for further use. The MoO₃ is purified via or acid leaching to remove impurities such as and silica, yielding high-purity technical-grade oxide suitable for downstream processing. This purified MoO₃ is then reacted with (NaOH) in large aqueous reactors at 50–100°C, where it dissolves to form a sodium molybdate solution through caustic extraction; the reaction is often conducted in stirred vessels to ensure complete dissolution. The resulting solution undergoes filtration to eliminate insoluble residues, followed by concentration through evaporation in multi-effect evaporators, an energy-intensive step due to the high requirements for removal. The concentrated liquor is then cooled in crystallizers to precipitate sodium molybdate dihydrate (Na₂MoO₄·2H₂O), which is separated by , washed, and dried to obtain the final product. Global production of sodium molybdate was approximately 50,000–70,000 tons in 2024, driven by demand in niche applications, with major manufacturing hubs in —accounting for about 40% of output as of 2023 due to its significant sector—and the . Production costs are heavily influenced by molybdenum ore prices, which can vary significantly based on global supply chains and economics, while byproduct management adds to operational expenses through gas scrubbing and acid production facilities.

Reactions

Reduction reactions

Sodium molybdate, featuring in the +6 , undergoes reactions that lower the through processes. These reactions are significant for synthesizing lower-valent compounds and in analytical applications. One prominent reduction method involves (NaBH₄) in aqueous medium at ambient temperatures, yielding metastable amorphous oxides of lower-valent , which upon heating crystallize to molybdenum(IV) oxide (MoO₂) and hydrogen gas as a byproduct. The balanced equation for this process is: \mathrm{Na_2MoO_4 + NaBH_4 + 2 H_2O \rightarrow NaBO_2 + MoO_2 + 2 NaOH + 3 H_2} The outcome depends on factors such as NaBH₄ concentration, reaction volume, and pH, influencing the degree of molybdate ion condensation prior to reduction. Other reductants include electrochemical methods, where sodium molybdate in acidic or neutral solutions exhibits stepwise reduction waves, typically at potentials around -0.8 V (vs. SCE) for the initial step to Mo(V) species and further to lower states like Mo(IV) or Mo(III) at more negative potentials. In analytical chemistry, controlled reduction of molybdate to Mo(V) enables speciation analysis, particularly in colorimetric techniques such as the molybdenum blue method, where partial reduction forms mixed-valence complexes for trace detection in environmental samples. The mechanism generally involves stepwise electron transfer to the Mo(VI) center, forming transient Mo(V) intermediates before further reduction to stable lower-valent products, as observed in both chemical and electrochemical pathways.

Coordination reactions

Sodium molybdate serves as a precursor for forming various coordination complexes through ligand exchange and oxo-transfer processes involving the tetrahedral molybdate ion, [MoO₄]²⁻. A notable reaction occurs with dithiophosphoric acids, (RO)₂P(S)SH (where R = methyl or ethyl), yielding neutral dioxomolybdenum(VI) complexes of the formula [MoO₂(S₂P(OR)₂)₂]. These bidentate dithiophosphate ligands coordinate to the molybdenum center, replacing two oxo groups and resulting in an octahedral geometry around Mo(VI). The simplified reaction can be represented as: \mathrm{Na_2MoO_4 + 2 (RO)_2P(S)SH \rightarrow [MoO_2(S_2P(OR)_2)_2] + 2 NaSH} This complex has been isolated and its confirmed through spectroscopic and crystallographic studies, demonstrating in non-aqueous . Beyond dithiophosphates, sodium molybdate participates in oxo-transfer reactions with oxidizing agents like , forming peroxomolybdate species such as [MoO(O₂)₂]²⁻, where η²-peroxo ligands bind to the metal center. These complexes exhibit distorted octahedral coordination and play a role in oxygen atom transfer , including the decomposition of H₂O₂ into water and oxygen. In analytical applications, sodium molybdate reacts with orthophosphate ions in acidic conditions to produce phosphomolybdate anions, exemplified by the Keggin-type [PMo₁₂O₄₀]³⁻, which upon reduction yields the intensely colored for spectrophotometric phosphate quantification. The coordination complexes derived from sodium molybdate, particularly the dithiophosphate variants like [MoO(S₂P(OEt)₂)₂], are employed as precursors or direct catalysts in organomolybdenum . These species facilitate selective transformations, such as the episulfidation of alkenes using sources, enabling efficient of thiiranes under mild conditions. Their tunable reactivity stems from the labile ligands and high of , making them valuable in developing catalysts for C-S bond formation and related organic processes.

Uses

Agricultural applications

Sodium molybdate serves as an essential source of , a critical for in leguminous crops such as soybeans and . In these , is a key component of the enzyme, which enables symbiotic bacteria to convert atmospheric into a form usable by the plant, thereby reducing the need for synthetic fertilizers. To address molybdenum deficiencies, sodium molybdate is applied to prevent conditions like whiptail disease in crops, including and , where leaves fail to expand properly due to impaired function. applications at rates of 0.1 to 1.0 effectively correct these deficiencies, promoting healthy growth and yield. It is also used as an additive in some formulations to supply . In formulation, sodium molybdate is commonly incorporated into fertilizers at rates such as 75 g per to ensure even distribution during planting, or used as foliar sprays for rapid uptake in deficient crops. Its availability in is influenced by , with optimal occurring at neutral levels between 6 and 7; in acidic soils below 6, molybdenum becomes less accessible, increasing deficiency risks. The addition of sodium molybdate enhances plant enzyme activity, facilitating the reduction of to and subsequent incorporation into proteins, which improves overall and crop productivity.

Industrial applications

Sodium molybdate serves as an effective in industrial applications, particularly in open and closed recirculating cooling systems and fluids. It is typically dosed at concentrations of 50-100 to protect metals such as mild , galvanized , and aluminum alloys from pitting and general . This usage allows for a significant reduction in the required levels of nitrite-based inhibitors, often cutting concentrations by up to 50% while enhancing overall protection in bimetallic systems. The compound performs optimally in alkaline conditions ( > 8), where it promotes the formation of protective molybdate films on metal surfaces, outperforming alternatives like chromates in environmentally sensitive applications. In , sodium molybdate acts as a key precursor for producing compounds used as additives in manufacturing, enhancing the strength and resistance of steels and superalloys. It is also incorporated as a component in enamels and frits, where it contributes to color stability and durability in high-temperature coatings for appliances and industrial equipment, and as an additive in dyes, such as a in or for pigments in inks. Additional industrial roles include its application as a additive in polymers and textiles, reducing flammability and smoke emission during by interfering with radical chain reactions. Sodium molybdate further functions as a precursor for catalysts in , particularly in hydrodesulfurization units that remove from fuels to meet environmental standards. In , it acts as a for detecting alkaloids and phosphates. In , it serves as an additive for capacitors and batteries to improve performance and stability. These non-agricultural uses collectively account for substantial industrial demand, with inhibition alone representing a major segment of global consumption.

Safety

Health hazards

Sodium molybdate has low , with an oral LD50 of 4,000 mg/kg in rats, indicating minimal risk from single exposures but potential for gastrointestinal irritation upon ingestion. At trace levels, from sodium molybdate is essential for human health, serving as a cofactor in molybdoenzymes involved in metabolic processes such as detoxification. However, chronic excess exposure can lead to molybdenosis, manifesting as joint pain (arthralgias), gout-like symptoms, and due to induced . Primary exposure routes for sodium molybdate include of dust in occupational settings and accidental , with dermal being limited. The National Institute for Occupational Safety and Health (NIOSH) recommends a (REL) of 5 mg per cubic meter (mg Mo/m³) as a time-weighted average for soluble molybdenum compounds like sodium molybdate. High-dose exposure may cause symptoms such as and , though these are more commonly observed in animal studies. Sodium molybdate is not classified as a by major regulatory bodies such as IARC, NTP, or OSHA, though some sources note possible effects from long-term exposure. Under the Classification, and (CLP) regulation, it is classified as Acute Tox. 4 (H302: Harmful if swallowed) and Eye Irrit. 2 (H319: Causes serious eye irritation). Appropriate (PPE) includes gloves, eye protection, and respiratory protection in dusty environments; for or , seek immediate medical attention.

Environmental effects

Sodium molybdate, through its release of the molybdate ion (MoO₄²⁻), exhibits variable aquatic toxicity depending on species and environmental conditions. In freshwater systems, acute toxicity to fish is generally low, with 96-hour LC₅₀ values ranging from approximately 70 mg Mo/L to over 2,000 mg Mo/L across species such as rainbow trout (Oncorhynchus mykiss) and fathead minnow (Pimephales promelas); for example, an LC₅₀ of approximately 609 mg Mo/L has been reported for P. promelas. Marine invertebrates demonstrate higher sensitivity than fish, with acute EC₅₀ values around 131 mg/L for Daphnia magna in controlled tests, indicating potential risks to coastal and estuarine ecosystems from elevated concentrations. Molybdenum from sodium molybdate can bioaccumulate in aquatic and terrestrial , though the extent varies inversely with environmental concentration. In , molybdenum uptake occurs readily via roots, accumulating in tissues and potentially reaching levels that inhibit growth and when exceeding essential thresholds (typically 0.1–1 mg/kg dry weight). Animals, including and , also bioaccumulate molybdenum, with bioconcentration factors (BCF) in aquatic organisms ranging from 1 to 10 at low exposures; in excess, it disrupts enzyme functions such as and sulfite oxidase, leading to and metabolic impairments. At trace levels, however, bioaccumulation does not pose risks to the , as molybdenum is an . The compound's high solubility (approximately 65 g/100 mL at 20°C) renders it persistent and highly mobile in the environment, facilitating dispersion through and without significant degradation. Agricultural runoff from molybdenum-containing fertilizers contributes to elevated levels, with reported increases of 1–5 mg/kg in fertilized fields, potentially leading to into waterways and . In the , sodium molybdate is assessed under the REACH framework, with derived predicted no-effect concentrations (PNEC) for freshwater at 11.9 mg Mo/L (chronic) and marine at 1.9 mg Mo/L, guiding monitoring in water bodies to prevent ecological harm.