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Keggin structure

The Keggin structure is a archetype in (POM) chemistry, consisting of a heteropolyanion with the general formula [XM₁₂O₄₀]^{n-}, where X represents a central tetrahedral (typically , , or other p-block elements) encapsulated by a shell of twelve edge- and corner-sharing {MO₆} octahedra (with M usually (VI) or (VI)). This highly symmetrical structure, exhibiting approximate tetrahedral (T_d) symmetry, self-assembles under acidic aqueous conditions and is renowned for its exceptional stability, tunable properties, and versatility in forming derivatives. First structurally characterized in 1933 by James F. Keggin through powder X-ray diffraction analysis of the phosphotungstate anion [PW₁₂O₄₀]^{3-}, it laid the foundation for modern POM research by resolving long-standing debates on heteropolyacid architectures proposed earlier by . The Keggin framework divides into four {M₃O₁₃} units, each comprising three {MO₆} octahedra sharing edges and corners, which collectively surround the central {XO₄} via oxygen bridges, resulting in a compact, nanometer-scale approximately 1 nm in diameter. Substitutions are common, including lacunary variants (with one or more M atoms removed) or mixed-addenda forms incorporating transition metals, which enhance reactivity for applications in , such as selective oxidation and acid-mediated transformations. These modifications also enable integration into hybrid materials, including metal-organic frameworks (MOFs) and , for and processes like electrocatalytic CO₂ . Beyond , the Keggin structure's and electron-transfer capabilities have found roles in , such as protein agents and antiviral agents, while its magnetic and luminescent properties support advancements in sensors and . Ongoing research explores its mechanisms and computational modeling to predict new derivatives, underscoring its enduring relevance as a for molecular metal clusters.

Introduction

Definition and Formula

The Keggin structure refers to a class of heteropolyoxoanion clusters in chemistry, characterized by a central tetrahedral encapsulated within a shell of twelve edge- and corner-sharing metal-oxygen octahedra. This arrangement forms a compact, cage-like that defines the α-isomer, the most common form of these anions. The first reported Keggin-type is , [NH₄]₃[PMo₁₂O₄₀], synthesized and reported by in 1826. The canonical formula for the Keggin anion is [\ce{XM12O40^{n-}}], where X represents the central , typically in a +3 to +6 (e.g., B^{3+}, Si^{4+}, P^{5+}, or As^{5+}), and M denotes the addenda atoms occupying the octahedral positions, most commonly ^{6+} or ^{6+}, with occasional incorporation of V^{5+} or Nb^{5+}. The overall charge n- balances the cationic contributions from X and the 12 M atoms against the 40 oxygen anions, yielding n = 8 - m, where m is the of X; for example, in the phosphomolybdate [PMo₁₂O₄₀]^{3-}, m = 5 and n = 3. This encapsulates the stoichiometric precision that enables the cluster's stability in aqueous and solid states. The 40 oxygen atoms in the Keggin anion are categorized into four distinct types based on their coordination environments: four central oxygen atoms forming the XO₄ (each bonded to X and three M atoms, providing the X–O–M bridges), twelve terminal oxygen atoms (each as a M=O ), and twenty-four bridging oxygen atoms linking pairs of addenda atoms via M–O–M connections (twelve of the edge-sharing subtype within structural triads and twelve of the corner-sharing subtype between triads). With an overall diameter of approximately 1 nm, the Keggin unit exemplifies a discrete nanoscale metal-oxide , bridging molecular and extended solid-state chemistries. Key structural metrics include average bond lengths of X–O ≈ 1.5 (central ), terminal M=O ≈ 1.70 , bridging M–O–M ≈ 1.9 , and M–O–X ≈ 2.43 , reflecting the localized electronic distribution and octahedral distortions.

Historical Background

The initial observation of polyoxometalates dates back to 1826, when reported the synthesis of , [NH₄]₃[PMo₁₂O₄₀], a yellow precipitate formed by the reaction of molybdic acid with and . This compound represented the first documented heteropolyanion, marking the beginning of interest in these cluster species. Early structural proposals emerged in the late 19th and early 20th centuries. In 1892, Christian Wilhelm Blomstrand suggested a chain or ring configuration for and related poly-acids to account for their composition. Building on coordination chemistry principles, proposed models in the early 1900s, applying ideas from complex ions to explain the structure of silicotungstic acid. In 1928, advanced a cage-like arrangement for α-Keggin anions, envisioning a tetrahedral central [XO₄]^{n-8} unit surrounded by twelve metal octahedra. The definitive elucidation of the Keggin structure came in 1933–1934 through James F. Keggin's X-ray crystallographic analysis of the hydrate H₃PW₁₂O₄₀·nH₂O, confirming the general [XM₁₂O₄₀]^{n-} and establishing the iconic of these heteropolyanions. Subsequent refinements after 1934, including improved studies, verified the α-isomer as the predominant and most stable form under typical conditions. Throughout the early , these compounds gained recognition as heteropoly acids, valued in for their use in gravimetric determinations and precipitating agents for elements like and cesium.

Core Structure

General Architecture

The canonical α-Keggin anion exhibits tetrahedral (T_d) symmetry, featuring a central X positioned at the core of a cage-like constructed from four {M₃O₁₃} units, where each unit comprises a trilobal arrangement of three edge-sharing MO₆ octahedra. This architecture derives from the general formula [XM₁₂O₄₀]^{n-}, with the {M₃O₁₃} triads rotated relative to one another to form a compact shell that encapsulates the heteroatom. The overall structure ensures that the central XO₄ is fully enclosed, promoting structural integrity through symmetric coordination. The 12 MO₆ octahedra (M = Mo or W) are interconnected via 24 μ₂-O bridges, which facilitate edge-sharing within each {M₃O₁₃} unit and corner-sharing between units, while the central tetrahedron connects to the shell via its four μ₄-O atoms, each bridging X and three M centers. Each octahedron coordinates to three terminal oxygen atoms pointing outward and three bridging oxygens, resulting in a highly symmetric polyhedral assembly that delocalizes the polyanion's negative charge across the oxygen framework and metal centers. This charge distribution contributes to the enhanced stability of the Keggin motif, as the cage-like enclosure shields the heteroatom from external interactions, minimizing reactivity at the core while exposing only the peripheral terminal oxygens. In typical ball-and-stick representations, the X appears buried within the opaque shell of interconnected octahedra, with the outward-projecting terminal oxygens forming a spiky exterior that underscores the molecular's nanoscale cage geometry. Variations in the addenda atom M influence properties: molybdenum-based Keggins (e.g., [PMo₁₂O₄₀]^{3-}) are more readily reducible, accommodating up to 24 electrons without structural collapse, whereas tungsten-based analogs (e.g., [PW₁₂O₄₀]^{3-}) exhibit greater oxidative stability due to stronger W-O bonds.

Isomerism

The Keggin structure exhibits isomerism through rotational variations of its four {M₃O₁₃} triads, each consisting of three edge-sharing MO₆ octahedra, relative to the central tetrahedron, resulting in five distinct Baker-Figgis isomers: α, β, γ, δ, and ε. These rotations occur by 60° around the axis connecting the heteroatom to the central μ₃-oxygen of a triad, altering the connectivity from corner-sharing in the α-isomer to increasing edge-sharing in higher isomers, while preserving the overall [XM₁₂O₄₀]^{n-} formula. The α-isomer represents the configuration, with all four s in unrotated positions exhibiting , making it the most common and thermodynamically stable form observed in most Keggin polyoxometalates. In contrast, the β-isomer arises from a single 60° of one , reducing symmetry to C_{3v} and introducing one pair of edge-shared octahedra, rendering it less stable than α but accessible under specific synthetic conditions such as heating in aqueous media. Higher-order isomers include the γ-form, featuring two adjacent triad rotations (C_{2v} symmetry, two edge-shared pairs), the δ-isomer with three rotations, and the ε-isomer with all four triads rotated, which maximizes edge-sharing (six pairs) and is the least stable in typical anionic Keggin systems but uniquely stabilizes certain cationic variants like the Fe₁₃ cluster due to favorable metal-ligand interactions. Interconversion between isomers, particularly α to β, proceeds via base-catalyzed rotation of the s, facilitated by attack or elevated in aqueous solutions, with favoring α (ΔG ≈ 2.1 kcal/) after prolonged heating (e.g., 473 K for days). Energy barriers for triad rotation are moderate (≈10-20 kcal/ for α ↔ β), but higher for γ, δ, and ε (up to 85 kcal/), often requiring alkaline conditions or templating ions to overcome, as computational studies confirm decreasing stability from α > β > γ > δ > ε in classical Keggin anions. Isomers are distinguished spectroscopically: ¹⁸³W NMR reveals symmetry-based signal patterns, such as a single peak for α (T_d), split into three signals (2:2:1 intensity) for γ (C_{2v}), and more complex splitting for β (e.g., additional peaks at -89 to -197 ppm). identifies isomers through shifts in M-O stretching bands (900-1000 cm⁻¹), where β and higher isomers show lower-energy modes due to increased edge-sharing, while ²⁷Al NMR (for Al-containing variants) detects distinct chemical shifts for rotated environments.

Derivative Structures

Lacunary Variants

Lacunary variants of the Keggin structure are incomplete clusters derived from the parent α-Keggin anion by the removal of one or more addenda metal-oxygen units, creating vacant sites that enhance reactivity. These defects typically involve the excision of corner-sharing MO₆ octahedra, leaving unsaturated oxygen atoms available for coordination. Monolacunary species, with one MO₆ unit missing, follow the general formula [XM_{11}O_{39}]^{(n+1)-}, where X is the central (e.g., P or ) and M is typically or , resulting in a higher negative charge compared to the saturated Keggin. A prominent example is [PW_{11}O_{39}]^{7-}, where the defect occurs at a specific position such as the 1,4 or 1,5 site in the α-Keggin framework, exposing four bridging and one terminal oxygen for metal binding. These structures maintain the overall but exhibit increased nucleophilicity at the lacuna due to the charge redistribution. Dilacunary variants, featuring two missing MO₆ units, have formulas such as [XM_{10}O_{36}]^{m-}, with elevated charges that confer even greater reactivity, though they are generally less stable than monolacunary forms. Common configurations include the 1,5- or 1,6-positions, often leading to γ-Keggin isomers like [\gamma-PW_{10}O_{36}]^{7-}, where the defects are positioned to form a larger cavity suitable for dinuclear metal incorporation. These species are prone to or rearrangement under acidic conditions but stabilize through coordination with transition metals or lanthanides. The stability of lacunary Keggin structures is pH-dependent, with higher pH values (typically 4–7) favoring defect formation via hydrolytic removal of units, while lower pH promotes reassembly to the intact . The unsaturated sites render these variants highly reactive toward electrophiles, enabling that saturated Keggins lack. For instance, monolacunary [PMo_{11}O_{39}]^{7-} serves as a versatile precursor in , where its lacuna facilitates metal substitution for applications in oxidative desulfurization of fuels, achieving high efficiency and recyclability due to the redox-active Mo centers. Lacunary Keggins are prized for their synthetic utility as building blocks, allowing controlled reassembly or incorporation of additional metals into the defects to form hybrid materials. In a 2023 study, the monolacunary compound K_8[PVW_{10}O_{39}] \cdot 15H_2O was synthesized via controlled acidification of a phosphovanadotungstate precursor at 5–6, yielding a stable with a V-substituted addenda position and a W-based lacuna, suitable for further complexation with transition metals. This approach highlights their role in tailoring polyoxometalate properties for advanced applications in catalysis and materials science.

Substituted and Cationic Forms

Substituted Keggin structures incorporate heteroatoms or cations from various groups, leading to variants with modified frameworks and charge distributions. For elements, the aluminum-based ε-Keggin ion [\text{Al}_{13}\text{O}_4(\text{OH})_{24}(\text{H}_2\text{O})_{12}]^{7+} features an all-aluminum framework with a central tetrahedral \text{AlO}_4 unit surrounded by 12 edge-sharing \text{AlO}_6 octahedra, exhibiting high symmetry of T_d and notable stability toward due to its coordinated ligands. A analogous structure exists for , the \text{Ga}_{13} Keggin polycation, which shares the same local coordination environment as \text{Al}_{13}, including a central \text{Ga}^{\text{IV}}\text{O}_4 tetrahedron and peripheral \text{Ga}^{\text{VI}} octahedra, with similar water coordination enhancing its aqueous persistence. Transition metal substitutions provide further diversity, as exemplified by the iron ε-Keggin cluster [\text{Fe}_{13}\text{O}_4(\text{OH})_{24}(\text{H}_2\text{O})_{12}]^{7+}, first isolated in 2015 through aqueous synthesis and characterized by , revealing a structure akin to the aluminum analog but with iron centers in mixed oxidation states. (II)-substituted variants, such as [\text{Co}^{\text{II}}W_{12}O_{40}]^{6-}, are known Keggin structures with in the central tetrahedral site, confirmed by earlier studies. More recent work in 2024 has explored Co(II)-substituted polyoxomolybdates like [\text{PCoMo}_{11}O_{40}]^{7-}, demonstrating their utility in such as . Other notable substitutions include boron-containing species, such as the sodium salt Na₇[H_{1.5}B^{III}W_{12}O_{40}]·6en, reported in 2025, where the heteroatom occupies the central tetrahedral site within the classic Keggin motif. Titanium-oxo additions represent advanced derivatives, including a 2023 example of a hexa-titanium [\text{Ti}_6\text{O}_6]-appended Keggin structure, where the \text{Ti}_6 unit integrates with the scaffold to form a hybrid . These incorporations often induce structural adaptations, such as the preference for the ε-isomer in high-charge cationic frameworks like those of \text{Al}_{13} and \text{Fe}_{13}, which rearranges the peripheral octahedra for enhanced stability. Lacunary sites in Keggin precursors can be filled by transition metals, yielding derivatives like [\text{PVW}_{10}\text{O}_{39}\text{M}(\text{H}_2\text{O})]^{n-}, where M denotes a metal such as Co or Fe coordinated to the defect position. Overall, such substitutions alter the net charge—often increasing it for cationic forms—and introduce additional coordination sites via aquo or oxo ligands, facilitating interactions in extended assemblies. These modified structures are typically derived from lacunary Keggin precursors like [\text{XM}_{11}\text{O}_{39}]^{n-}.

Physical Properties

Stability and Solubility

The Keggin anions, particularly those based on tungsten such as [PW_{12}O_{40}]^{3-}, exhibit high thermal stability, remaining intact up to approximately 400–500 °C before decomposing into metal oxides like WO_3. In contrast, molybdenum-based analogs like [PMo_{12}O_{40}]^{3-} show lower thermal stability, preserving the Keggin framework up to around 300 °C, with subsequent decomposition to MoO_3 and other oxides. This difference arises from the stronger W–O bonds compared to Mo–O bonds, enhancing the robustness of the tungsten cage under elevated temperatures. Hydrolytic stability of canonical Keggin anions is pronounced in acidic conditions, with [PW_{12}O_{40}]^{3-} maintaining structural integrity at pH < 1.5 and [PMo_{12}O_{40}]^{3-} stable up to pH ≈ 0–2, but both undergo disassembly into lacunary species at higher pH values (e.g., pH > 3.5 for tungsten-based). Lacunary variants, such as [PW_{11}O_{39}]^{7-}, are inherently less stable hydrolytically due to the missing metal center, which weakens the overall cage and promotes faster and fragmentation. The closed Keggin architecture provides greater resistance to than simpler or species by distributing and limiting access to reactive sites. Keggin acids and their salts display high solubility in water and polar solvents, with H_3PW_{12}O_{40} being fully miscible in water (up to 200 g/100 mL) yet insoluble in nonpolar media like hydrocarbons. Common crystalline hydrates, such as H_3PW_{12}O_{40}·6H_2O, further underscore this solubility, though it diminishes with larger counterions; for instance, cesium salts like Cs_3PW_{12}O_{40} exhibit reduced aqueous solubility compared to sodium or protonated forms due to increased and hydrophobicity. This solubility profile, modulated by the and of counterions, facilitates their use in solution-based processes while the robust resists disassembly under typical conditions.

Spectroscopic Characteristics

Infrared (IR) is a primary technique for identifying the Keggin structure, revealing characteristic vibrational bands associated with the polyanion framework. For the archetypal α-Keggin anion [PW_{12}O_{40}]^{3-}, the asymmetric stretching mode of the P-O bond (P-O_a) appears at approximately 1080 cm^{-1}, while the terminal W=O (W=O_d) stretch is observed around 980 cm^{-1}, and the asymmetric stretching of the corner-sharing W-O_b-W bridges occurs in the 870-800 cm^{-1} region, often splitting into bands near 890 and 810 cm^{-1}. These assignments, established through detailed vibrational analysis, confirm the intact Keggin motif and are applicable to analogs like phosphomolybdates, where bands shift slightly due to the lighter metal (e.g., Mo=O_d at ~990 cm^{-1}). Deviations, such as splitting of the 870 cm^{-1} band into distinct components around 880 and 860 cm^{-1}, indicate isomerism, particularly the β-form, allowing differentiation from the α-isomer. Raman spectroscopy complements IR by enhancing symmetric stretching modes, providing insights into the Keggin structure, especially in aqueous solutions where IR transmission is limited. Key Raman bands mirror IR features, with strong signals for the symmetric M=O_d stretch at ~950-1000 cm^{-1} and M-O-M vibrations in the 800-900 cm^{-1} range, offering higher resolution for metal-oxygen bonds in and variants. For instance, in [PMo_{12}O_{40}]^{3-}, prominent Raman peaks at 995 cm^{-1} (Mo=O_d) and 940 cm^{-1} (Mo-O-Mo) confirm framework integrity, with solvent interactions causing minor shifts but preserving diagnostic patterns. This technique is particularly valuable for studies of solutions, as the polarized nature of Raman signals highlights subtle distortions in the octahedral MO_6 units. Nuclear magnetic resonance (NMR) spectroscopy, particularly ^{31}P NMR, serves as a sensitive for the environment in Keggin structures, with chemical shifts reflecting the surrounding metal-oxygen cage. In the α-Keggin phosphomolybdate [PMo_{12}O_{40}]^{3-}, a single sharp at -2 to -3 indicates the symmetric tetrahedral PO_4 , while phosphotungstates like [PW_{12}O_{40}]^{3-} exhibit a downfield shift to approximately -15 due to increased ionic character in W-O bonds. Lacunary derivatives, such as [PW_{11}O_{39}]^{7-}, show multiple signals (e.g., two differing by 1-2 ) arising from reduced and inequivalent environments upon metal removal. Substituted forms further diversify the spectrum; for example, incorporation in [PV_xMo_{12-x}O_{40}]^{n-} produces additional shifted upfield by 2-5 , enabling quantification of substitution . These shifts are influenced by solution and counterions, but the single- signature remains diagnostic for intact α-Keggin units. Ultraviolet-visible (UV-Vis) spectroscopy detects ligand-to-metal charge-transfer (LMCT) transitions in Keggin polyanions, with broad absorption bands in the 200-300 nm range arising from O^{2-} to M^{6+} (M = Mo, W) excitations. These oxygen-to-metal charge-transfer bands, peaking near 220 nm for molybdates and 260 nm for tungstates, provide a measure of electronic delocalization and are used to monitor reduction states, as partial reduction shifts the edge to longer wavelengths (e.g., 300-400 nm for Mo^{V} species). In heteropolyacids, the absorption edge correlates with redox potential, with vanadium-substituted variants showing intensified bands around 300 nm due to V^{5+} contributions. X-ray crystallography definitively confirms the Keggin structure, with James F. Keggin's 1933 powder diffraction analysis of 12-phosphotungstic acid establishing the [PW_{12}O_{40}]^{3-} anion as a central PO_4 tetrahedron surrounded by four {PW_3O_{12}} trimers, featuring 12 edge- and corner-shared WO_6 octahedra. Modern single-crystal studies extend this to derivatives, resolving subtle distortions in substituted forms; for example, cobalt-substituted [PCoW_{11}O_{40}]^{5-} reveals Co integration into the framework with bond lengths confirming octahedral coordination.

Chemical Properties

Acid-Base Behavior

Keggin heteropolyacids exhibit exceptionally strong Brønsted acidity, arising from the delocalization of protons over the polyanion framework, which stabilizes the negative charge and enhances proton mobility. This delocalization results from the large size of the Keggin anion, allowing the protons to behave as counterions distributed across multiple oxygen atoms rather than being localized on a single site. The superacidity of these compounds is exemplified by phosphotungstic acid (H₃PW₁₂O₄₀), which achieves a Hammett acidity function H₀ < -12 in its anhydrous form, surpassing that of concentrated sulfuric acid (H₀ ≈ -12) and qualifying it as a superacid. This extreme acidity stems from the ability of the Keggin structure to support highly dissociated protons without significant self-association, enabling applications in acid-catalyzed processes. Protonation in Keggin heteropolyacids occurs primarily at terminal oxygen atoms (W=O) and bridging oxygen atoms (W-O-W), with site preferences varying by metal composition; for instance, in H₃PW₁₂O₄₀, terminal oxygens are favored in the anhydrous state, while bridging sites dominate in H₃PMo₁₂O₄₀. In the pseudoliquid phase—where polar molecules dissolve into the bulk crystal lattice, mimicking liquid-like behavior—the anion can accommodate up to 40 protons per Keggin unit, corresponding to the total number of oxygen atoms available for protonation and facilitating high proton conductivity. The pKₐ values reflect a stepwise decrease in acidity: the first three protons of H₃PW₁₂O₄₀ are strong acids with pKₐ < 0, fully dissociating in aqueous solution, while subsequent protonations are weaker due to increasing electrostatic repulsion on the highly charged anion. In salt forms, such as the sodium salt , the acidity is significantly reduced because the alkali metal cations replace mobile protons, limiting dissociation. Similarly, the in cesium salts (e.g., ) shows modulated acidity, with Cs⁺ ions further decreasing proton availability and strength compared to the free acid, often tuning the material for selective acid catalysis.

Redox Reactivity

The Keggin structures of polyoxometalates exhibit pronounced multi-electron redox activity, primarily involving the addenda atoms molybdenum and tungsten, with molybdenum(VI)/molybdenum(V) reductions being more facile and common than tungsten(VI)/tungsten(V) counterparts due to the lower reduction potentials of Mo-based clusters. These clusters can accommodate up to 24 electrons in their fully reduced state, as exemplified by the transformation of the phosphotungstate anion [ \ce{PW_{12}O_{40}}^{3-} ] to [ \ce{PW_{12}O_{40}}^{27-} ], enabling them to act as electron reservoirs in various chemical processes. This capacity arises from the delocalized nature of the lowest unoccupied molecular orbitals (LUMOs) across the metal-oxygen framework, facilitating sequential electron uptake without structural collapse. The redox processes in Keggin anions are highly reversible, with the first reduction of phosphotungstate occurring at approximately 0 V versus the normal hydrogen electrode (NHE) in aqueous media. Cyclic voltammetry of these species typically reveals up to six distinct one-electron reduction waves, reflecting stepwise electron addition to the tungsten centers while maintaining structural integrity. These potentials can shift slightly based on counterions or solvent effects, but the overall reversibility underscores the stability of the reduced forms, making Keggin clusters suitable for electrochemical applications. Upon reduction, Keggin structures form mixed-valence states known as heteropoly blues, particularly in molybdenum-containing variants where Mo(VI)/Mo(IV) intervals dominate, leading to characteristic color changes from pale yellow to intense blue due to intervalence charge transfer bands in the visible spectrum. These blues retain the primary Keggin framework but exhibit enhanced electronic delocalization, which influences their reactivity in electron-transfer reactions. Lacunary Keggin derivatives, formed by removal of one or more addenda atoms, display amplified redox reactivity, especially when substituted with transition metals, as the vacancies lower the reduction potentials and increase coordination sites for further electron storage or catalytic mediation. Recent advancements have leveraged these properties in composite materials, such as ε-Keggin polyoxometalate-based metal-organic frameworks, which demonstrate efficient electrocatalytic hydrogen evolution with sustained activity over 1000 cycles, attributed to the framework's ability to facilitate multi-electron transfers at accessible potentials.

Synthesis

Classical Methods

The classical synthesis of canonical Keggin anions relies on the acidification of aqueous solutions containing a heteroatom source and addenda metal oxides, promoting condensation to form the polyanion structure. A typical procedure involves mixing a phosphate source, such as Na₂HPO₄, with an addenda source like Na₂WO₄, followed by acidification using HCl or H₂SO₄ to achieve a pH of 1–2, which facilitates the assembly of the [PW₁₂O₄₀]³⁻ unit. This method, adapted from early heteropolyacid preparations, proceeds via protonation and dehydration of the metalate species under controlled conditions. The reaction for phosphotungstate formation can be represented by the balanced equation: \ce{PO4^3- + 12 WO4^2- + 27 H+ -> H3PW12O40 + 12 H2O} This yields the free heteropolyacid H₃PW₁₂O₄₀, with the process often requiring excess acid to drive complete condensation. Isolation of the free acid from the aqueous reaction mixture traditionally employs extraction, where ether is added to the acidic solution, causing the Keggin species to partition into a dense oily that separates from the aqueous layer; subsequent of this affords crystalline H₃PW₁₂O₄₀. This technique, originally described by Drechsel in , remains a cornerstone for obtaining pure heteropolyacids despite its limitations in . Syntheses are conducted either at room temperature or under reflux (boiling), with tungsten-based Keggins achieving yields greater than 90%, while molybdenum analogs typically yield lower due to competing side reactions and reduced stability. An early precedent for such precipitation methods was Berzelius' 1826 preparation of phosphomolybdate by adding phosphoric acid to an ammonium molybdate solution, marking the initial isolation of a Keggin-type species. These classical routes produce stable [XM₁₂O₄₀]^{n-} anions suitable for further salt formation or application.

Modern Techniques

Modern techniques for synthesizing Keggin structures have evolved significantly since 2000, emphasizing scalable methods to produce substituted derivatives and nanostructures under controlled conditions. These approaches address limitations of classical methods by enabling precise incorporation of transition metals, formation of hybrid materials, and rapid assembly, often leveraging advanced reactors and energy sources for improved yield and purity. Hydrothermal synthesis, involving high temperatures (100–200°C) and pressures in autoclaves, facilitates the formation of substituted Keggin polyoxometalates by promoting condensation and metal incorporation in aqueous media. For instance, a -substituted trilacunary Keggin-type polyoxotungstate was prepared via one-pot hydrothermal reaction of sodium , salts, and precursors, yielding stable complexes suitable for further derivatization. This method's versatility allows for the isolation of frameworks integrating intact Keggin units, such as [SiW₁₂O₄₀]⁴⁻ linked with complexes at 120°C for 3 days, enhancing structural diversity. The sol-gel approach enables the creation of nanostructured Keggin-based materials at low with polyvalent cations, directing into hierarchical forms like microspheres. In a 2024 study, was combined with polyvalent cations such as Ti(IV) under acidic conditions ( < 0) to form stable, porous microspheres with preserved Keggin integrity, demonstrating high thermal stability up to 500°C. This technique builds on classical acidification but offers better control over morphology for advanced applications. Template-assisted methods support the reassembly of lacunary Keggin species, using stabilizing agents to guide in situ incorporation of elements. A reliable 2023 procedure synthesized the trilacunary [PMo₉O₃₄]⁹⁻ via pH-controlled degradation of the parent Keggin, followed by nanofiltration purification, enabling subsequent metal substitution. Similarly, boron-substituted Keggins, such as Na₇[H₁.₅BW₁₂O₄₀]·6en, were obtained in 2025 through hydrothermal synthesis with precise pH adjustment to stabilize the B-centered structure, confirmed by single-crystal X-ray diffraction. Integration of Keggin units into metal-organic frameworks (MOFs) represents a hybrid strategy for functional materials. In 2021, an ε-Keggin polyoxometalate was incorporated into a Zn-based MOF via solvothermal assembly, yielding a porous network with overpotential of 417 mV (at 10 mA/cm²) for hydrogen evolution reaction, retaining activity after 1000 cycles. Microwave-assisted synthesis accelerates the preparation of lacunary and substituted Keggins by enhancing reaction kinetics. Microwave irradiation is particularly effective for sensitive derivatives, avoiding prolonged heating.

Applications

Catalysis

Keggin-type heteropolyacids (HPAs), particularly phosphotungstic acid \ce{H3PW12O40}, serve as highly effective catalysts for acid-mediated processes due to their strong Brønsted acidity and ability to form a pseudoliquid phase that enables bulk catalysis beyond surface sites.00386-7) In hydration reactions, such as the conversion of alkenes to alcohols, \ce{H3PW12O40} supported on metal oxides facilitates the gas-phase hydration of propene to 2-propanol at atmospheric pressure and 85°C, achieving conversions up to 10% with selectivities exceeding 90% under photo-assisted conditions. For polymerization, cesium or ammonium salts of Keggin HPAs promote the cationic polymerization of isobutene to polyisobutene, providing molecular weight control and reduced side reactions compared to conventional AlCl₃ systems, with catalyst loadings as low as 0.1 mol% yielding polymers of 500–5000 Da. The pseudoliquid phase of \ce{H3PW12O40} is particularly advantageous, as it allows polar reactants to penetrate the catalyst lattice, enhancing reaction rates by factors of 10–100 relative to purely surface-active solids. In oxidation catalysis, molybdenum-based Keggin HPAs, such as \ce{H3PMo12O40} and vanadium-substituted variants like \ce{H5PMo10V2O40}, are prized for their selective redox properties, enabling oxygen atom transfer from oxidants like H₂O₂ or O₂. These catalysts support the epoxidation of propene to propylene oxide in biphasic systems with peroxo-heteropoly compounds, attaining yields of 20–30% at mild temperatures (40–60°C) when combined with palladium promoters for O₂ activation. Similarly, in the selective oxidation of methacrolein to methacrylic acid, phosphorus-molybdenum-vanadium Keggin structures (e.g., \ce{H4PMo11VO40}) deliver selectivities above 80% at conversions of 50–70%, with the vanadium centers facilitating reoxidation of reduced molybdenum sites. The mechanisms hinge on proton transfer for acid activations, where delocalized protons from the Keggin anion initiate carbocation formation, and oxygen atom transfer for oxidations, involving peroxometal intermediates that donate electrophilic oxygen to substrates. To enhance practical utility, Keggin HPAs are often heterogenized by immobilization on high-surface-area supports like silica or encapsulation in polymeric matrices, which preserves the intact Keggin structure while enabling facile recovery and reuse over multiple cycles with minimal leaching (<1%). For instance, silica-supported \ce{H3PW12O40} maintains activity in acid catalysis for over 10 runs, with surface areas up to 300 m²/g improving mass transfer. Turnover numbers in these systems can exceed 1000, as seen in the alkylation of benzene with 1-dodecene over SBA-15-supported \ce{H3PW12O40}, where linear alkylbenzenes form with 90% selectivity at 28% olefin conversion. Industrially, Keggin HPAs have found application in the etherification of methanol with isobutene to produce methyl tert-butyl ether (MTBE), utilizing Dawson or Keggin acids in fixed-bed reactors at 70–100°C for conversions >98%, though this process was phased out in many regions due to concerns.00134-3) They continue to play a role in fine chemicals production, such as via methacrolein oxidation, where supported Mo-V-P catalysts operate continuously with space-time yields of 1–2 g/mL·h. These applications capitalize on the reactivity of Keggin units, as outlined in prior sections on chemical properties.

Emerging Uses

Recent advancements in Keggin-type polyoxometalates (POMs) have expanded their utility beyond traditional into interdisciplinary fields, particularly , , and . These emerging applications leverage the tunable properties, structural stability, and of Keggin structures, often enabled by modern synthetic techniques such as ion-exchange and templated assembly. In , Keggin POMs exhibit promising antiviral, antibacterial, and anticancer activities. A sodium salt of boron-substituted Keggin-type POM, synthesized in 2025, demonstrates significant antimicrobial efficacy against like Bacillus cereus and Gram-negative strains, attributed to its disruption of bacterial cell membranes and induction. Similarly, Keggin POMs such as [PW12O40]3- and vanadium-substituted variants bind to calf thymus DNA through electrostatic and groove interactions, inhibiting tumor cell proliferation and inducing in cancer cell lines like HeLa and SGC-7901 via DNA cleavage and arrest. These properties position Keggin POMs as candidates for next-generation metallodrugs targeting resistant pathogens and malignancies. For , Keggin POMs enhance the durability and performance of electrodes. In 2025, a Keggin-type POM coating on LiNi0.8Mn0.1Co0.1O2 cathodes improved cycling stability by mitigating structural degradation and suppressing side reactions, achieving over 90% capacity retention after 200 cycles at 1C rate. Keggin-based photocatalysts show potential in conversion, particularly for (HER) and CO2 reduction. An ε-Keggin POM-integrated metal-organic framework (MOF), reported in 2021, catalyzes electrochemical HER with an of 417 mV at 10 mA/cm² and Tafel slope of 68 mV/dec, maintaining activity over 1000 cycles due to the ε-isomer's enhanced and . For CO2 reduction, Keggin POM nanostructures, such as those combined with metalloporphyrins or Ag nanocomposites, selectively produce CO with Faraday efficiencies exceeding 80%, leveraging the POM's role as an electron/proton reservoir to stabilize intermediates. In , sol-gel-derived Keggin microspheres offer versatile platforms for electrocatalytic applications. Phosphotungstic acid-based microspheres, synthesized in via low-pH sol-gel processes with polyvalent cations, form hierarchical nanostructures with 20 nm secondary spheres, exhibiting a surface area of 100.6 m²/g suitable for reaction (OER) electrocatalysis. These materials also enable antibacterial coatings; for instance, polyoxotungstate-ionic hybrids incorporated into films provide sustained antimicrobial activity against and , reducing bacterial growth by 100% via generation. Polyoxometalate-organic frameworks (POMOFs) incorporating mono-lacunary units represent a frontier in porous materials for gas storage.