1. Chemical context

Isopolytungstates are a class of polyoxidometalates (POMs). They are sometimes described as anionic mol­ecular oxides of d-block metals with no additional elements, aside from the counter-ions. These discrete metal-oxygen mol­ecules are often composed of octa­hedrally coordinated metal ions, bridged by oxygen ions. The elements forming POMs are typically high-oxidation state metals, such as W^VI, Mo^VI, Nb^V, Ta^V, etc. (Pope, 1983). Polytungstate formation is often seen as a result of controlling hydrolysis and condensation reactions, which otherwise results in an oxide. Structural and compositional variability of polytungstates increases with the incorporation of other elements, such as phosphates or silicates (Wang et al., 2024), which are named heteropolytungstates. Nevertheless, factors such as counter-ions and concentration can and have influenced the formation of metal-oxido species, becoming a more popular avenue to obtain new compounds with new structures (Antonio et al., 2009). The number of isopolytungstate general structures has so far been limited to a handful, e.g. [W₄O₁₆]^8–, [W₆O₁₉]^2–, [W₇O₂₄]^6–, [W₁₀O₃₂]^4–, [H₂W₁₂O₄₀]^6–, [H₂W₁₂O₄₂]^10– and others (Liu et al., 2018). The corresponding compounds have generated growing inter­est since their original discovery because of their diverse chemical and physical properties, making them of considerable value in various fields including catalysis, optics, quantum devices, materials sciences, medicine, and beyond.

2. Structural commentary

The hydrated mixed alkali isopolytungstate, fully formulated as Na₅Cs₁₉(H₂O)₂₁W₂₄O₈₄, crystallizes in the trigonal space group R with an obverse rhombohedral centering. This compound is based on the tetra­cosa­tungstate(VI) core: [W₂₄O₈₄]^24– (Fig. 1). Before detailing the inter­connectivity, description of the symmetry elements present will aid in the construction of the core anion. The [W₂₄O₈₄]^24– isopolytungstate anion can best be described by the point group S₆ otherwise known as C_3i. The anion thus only has threefold improper rotation symmetry around an inversion point that is outside the anion, within the central void (Fig. 1). Considering only the asymmetric unit of the anion, an octa­meric [W₈O₂₈]^8– subunit is present, disregarding the counter-ions at the moment. Applying the threefold improper rotation on the asymmetric unit creates the complete anion. An alternate view can be seen through the deconstruction of the asymmetric unit into smaller substructures, [W₄O₁₄]^4–, i.e. two tetra­mers fused together. The smaller tungstate subunit can be seen as three six-coordinate W atoms (W2, W3, and W4, or W6, W7, and W8), with a W—O bond length range of 1.771 (10)–2.293 (9) Å (average 1.956 Å), plus one five-coordinate W atom (W1 or W5) with a bond length range of 1.732 (12)–2.008 (9) Å (average 1.867 Å). W1 and W5 uniquely feature two terminal O atoms with bond lengths between 1.732 (12) and 1.765 (9) Å. In contrast, the six-coordinate W atoms have only one terminal O atom, with the remaining five oxygen atoms bridging to neighboring W atoms. The W atoms are arranged in a kite shape with the three six-coordinate W atoms (W2, W3, and W4) making the tip and the five-coordinate W atom (W1) making the cap (Fig. 2). The tetra­meric subunits are linked up through the ‘tip-most’ tungstate, i.e. W4 or W8. Each of these W atoms bridges to the neighboring tetra­mer; W4 is bound to W6, W7, and W8. The other ‘tip-most’ W atom, W8 thus does the same (bridged to W2, W3, and W4). Thus, the anion takes on a hexa­gonal shape with the five-coordinate W atoms on the periphery, alternating above or below a plane created by the central W4 and W8 atoms. Two unique cesium counter-ions (Cs1 and Cs2) fill the void left by the anion both with a twelve coordination and a Cs—O bond length range of 3.139 (9)–3.657 (9) Å. These Cs atoms are actually located on the same axis as the threefold improper rotation symmetry operation (1/3, 2/3, z, Wyckoff letter c) representing a special symmetry position for the space group, consistent with the obverse centering. The remaining Cs⁺ counter-ions fill in the space made by linking the tetra­meric units in a pinwheel structure and connect to the neighboring [W₂₄O₈₄]^24– anion making the long-range structure. Cs6 is the only counter-ion located at the edge of the unit cell on another threefold rotation axis (1, 1, z). The sodium counter-ions, on the other hand, feature higher hydration (in terms of bound water O atoms) than connectivity to the O atoms of the tungstate anions, in line with the typical higher polytungstate inter­actions with larger alkali cations, relative to small ones (Misra et al., 2020). Four of the sodium counter-ions can be located in between [W₂₄O₈₄]^24– units, making a sodium-based tetra­meric [Na₄(H₂O)₁₅] unit with an Na—O bond length range of 2.380 (16)–2.508 (19) Å (more in the next section). The sodium counter-ion Na2 and Cs8 are also at special symmetry positions (2/3, 1/3, z). The remaining Na⁺ counter-ion, Na3, is disordered over three positions and links water mol­ecules along the c axis.

Figure 1 Ellipsoid and stick representation of the [W24O84]24– polyoxidotungstate anion at the 50% probability level. The shown counter-ions and O atoms of solvent water mol­ecules represent those from the asymmetric unit (see Fig. 2). Color code: W in maroon, Cs in light blue, Na in green, and O in red.

Figure 2 Ball-and-stick representation of the asymmetric unit, comprised of two [W4O14]4– building blocks, showing the five-coordinate W1 and W5 atoms. The tip of the tetra­mer (W4) connects to the next tetra­mer, which W8 then repeats; the whole asymmetric unit needs to be repeated three times to complete the entire anion. Counter-ions, O atoms of solvent water mol­ecules, and oxygen labels are omitted for clarity. Color code: W in maroon and O in red.

3. Supra­molecular features

The unique structure formation for [W₂₄O₈₄]^24– is mainly attributed to the Na⁺ counter-ions. The section above described the formation of the [Na₄(H₂O)₁₅] unit, where the Na⁺ cations are triangularly arranged, with one central Na⁺ cation linked to three other Na⁺ cations (Fig. 3). As such, each corner of the triangle formed by the Na⁺ centers links to one [W₂₄O₈₄]^24– anion, hence arranging the [W₂₄O₈₄]^24– anions into the hexa­gonal sheets. The Cs⁺ counter-ions additionally link [W₂₄O₈₄]^24– along the c axis (Fig. 3).

Figure 3 Projection of the crystal structure along [001] in a polyhedral representation of the [W24O84]24– (maroon) and [Na5(H2O)18]5+ (green) units, showcasing the long-range structure formation, connectivity and unit cell. Cs+ counter-ions are in blue, Na+ in green.

Since water H atoms could not be located, details of possible hydrogen-bonding inter­actions were approximated by calculating the shortest O⋯O distances for the water mol­ecules, which were measured to be on average 2.8 Å (Table 1).

4. Database survey

A search of the Inorganic Crystal Structure Database (ICSD-408188, release 2024.1 version 5.2.0; Zagorac et al., 2019) and the Cambridge Structural Database (CSD, accessed on April 2024; Groom et al., 2016) for closely related sodium cesium polyoxidotungstates was performed. The first search involved a unit cell search (a = b = 17.998 Å, c = 62.879, α = β = 90°, and γ = 120°, with tolerance of 10% each). With a rhombohedral centering no results were found, with a primitive setting six results were found, none of which contained any tungstates. Therefore, a second search was conducted based on the general anion formula `W₂₄O₈₄' with the option to allow other elements in the mol­ecule. Two matches were received: first is Cs₂₄[W₂₄O₈₄]·26H₂O, which features the anion with all Cs⁺ counter-ions, but with lower point group symmetry (C_i) in comparison with the title compound (deposition number 408188, reference code 1725526; Brüdgam et al., 1998). Therein the authors suggest that the anion could only be isolated with Cs⁺ counter-ions, with no other alkali. However, the new structure confirms the essence of Cs⁺ to template the [W₂₄O₈₄]^24– anion, as well as the role Na⁺ can have in long-range structure formation. The second, (C₁₂H₃₅As₂Mn₃N₂O₁₀₅P₄W₂₄^9–)_n·6(C₂H₈N⁺)·7(H₂O)·1.2(K⁺)·2.4(Li⁺)·0.6(Cl⁻), deposition number 2251558, reference code CODJUE, can best be described as a fragment of the [P₅W₃₀O₁₁₀]^14– anion (Iftikhar et al., 2024). Further extensive searches with varying compositions and unit-cell tolerances were performed, but no additional structures were found.

5. Synthesis and crystallization

All materials herein were obtained and used as received, with no need for further purification: NaCl (>=99.9%), NaCH₃COO (>=99.9%), cesium chloride (>99.99%), and Na₂WO₄·2H₂O (>=99%). All solutions were prepared using deionized water purified by reverse osmosis cartridge system (>= 18.2 MΩ.cm). All experiments were performed in a temperature-controlled room (295 K). Na₂WO₄·2H₂O was dissolved in 50 ml of boiling water. The pH of the solution was adjusted to 7.2 with 6 M HCl added dropwise. After boiling the solution for 1 h the volume reduced to 20 ml. Then, 5 g NaCl were added, and the solution was left to cool to 278 K. Sodium paratungstate A crystallized out and was collected. The resulting sodium paratungstate A, formulated as Na₁₀H₂W₁₂O₄₂·nH₂O (10 g), was dissolved in 20 ml of boiling water. After complete dissolution, 10 g of CsCl were added, and the solution was left to cool. Immediately upon reaching room temperature, crystals of the title compound appeared.

Raman spectra were collected using a Senterra II confocal Raman microscope (Bruker), equipped with high resolution gratings (1200 lines mm⁻¹) and a 532 nm laser source (operated at 15 mW), and a TE-cooled CCD detector. The shown spectrum is based on the average of at least 2–5 different spots per sample, each spot analysis consisting of 2 binned 16 scans. The integration time was set to 2000 ms per scan. No damage to the sample was observed due to the laser irradiation. Selected Raman data (cm⁻¹): ν(W=O^t) 930 and 901, and ν(O—W—O) 703, 364, 314 and 207 (Fig. 4).

Figure 4 Solid-state Raman spectrum of Na5Cs19[W24O84]·21H2O.

6. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 2. All atoms were refined anisotropically, except for two O atoms of water mol­ecules (O1W and O4W). In addition, Na3 was first refined with a free site occupation factor which converged to a value of 0.333 to which it was fixed for charge balance in the final refinement cycles. Hydrogen atoms of the water mol­ecules could not be located and are not part of the model but are considered in the formula and other crystallographic data. Due to the high atomic number (Z) for W and Cs atoms, high residual electron-difference peaks of about 10% of Z Å⁻³ remained, which is considered as inconspicuous (Massa & Gould, 2004); the highest residual peak is located at 0.452 Å from the nearest W atom.

Table 2 Experimental details Crystal data Chemical formula Na5Cs19[W24O84]·21H2O Mr 8774.97 Crystal system, space group Trigonal, R Temperature (K) 298 a, c (Å) 18.0071 (3), 62.9142 (9) V (Å3) 17667.1 (6) Z 6 Radiation type Mo Kα μ (mm−1) 29.24 Crystal size (mm) 0.02 × 0.02 × 0.01   Data collection Diffractometer ROD, Synergy Custom DW system, Pilatus 300K Absorption correction Multi-scan (CrysAlis PRO; Rigaku OD, 2019) Tmin, Tmax 0.001, 0.007 No. of measured, independent and observed [I > 2σ(I)] reflections 30484, 8019, 7262 Rint 0.033 (sin θ/λ)max (Å−1) 0.625   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.062, 0.170, 1.08 No. of reflections 8019 No. of parameters 456 H-atom treatment H-atom parameters not defined Δρmax, Δρmin (e Å−3) 5.28, −1.53 Computer programs: CrysAlis PRO (Rigaku OD, 2019), SHELXT (Sheldrick, 2015a), SHELXL (Sheldrick, 2015b) and OLEX2 (Dolomanov et al., 2009).