1. Chemical context

Non-centrosymmetric (NCS) compounds are widely studied as they have potentially useful symmetry-dependent properties such as piezoelectricity, ferroelectricity and second-order non-linear optical (NLO) behaviour (Halasyamani & Poeppelmeier 1998). Many crystalline selenites and tellurites containing d⁰ transition-metal ions such as V⁵⁺, Mo⁶⁺, W⁶⁺ are non-centrosymmetric compounds. The solid-state chemistry of these oxides is inter­esting from the point of view of both structural diversity and second harmonic generation (SHG) activity. They have two types of second-order Jahn–Teller (SOJT) distortion. One is the distorted octa­hedral coordination of the d⁰ transition-metal ion and the other is pyramidal, disphenoidal and square-pyramidal coordinations of Se⁴⁺ and Te⁴⁺, which have stereoactive lone pairs. Both SOJT distortions lead to acentric coordination environments that are conducive for NCS structures (Halasyamani 2004). For example, Cs₂Mo₃TeO₁₂ (Vidyavathy Balraj & Vidyasagar, 1998) and YVSe₂O₈ (Kim et al., 2014) have non-centrosymmetric layered structures with these SOJT distortions and exhibit SHG activity. It needs to be mentioned that quaternary selenites and tellurites containing d⁰ transition-metal ions, such as YVTe₂O₈ (Kim et al., 2014), are also known to have centrosymmetric structures and exhibit no SHG activity.

A₂Mo₃SeO₁₂ (A = NH₄, Cs, Rb, Tl) (Harrison et al., 1994; Dussack et al., 1996; Chang et al., 2010), A₂W₃SeO₁₂ (A = NH₄, Cs, Rb, K) (Harrison et al., 1995; Huang et al., 2014a,b) and Na₂W₃SeO₁₂·2H₂O (Nguyen & Halasyamani 2013), A₂Mo₃TeO₁₂ (A = Cs, NH₄) (Vidyavathy Balraj & Vidyasagar 1998), A₂W₃TeO₁₂ (A = K, Rb and Cs) (Goodey et al., 2003; Zhao et al., 2015) are the 14 quaternary selenites and tellurites of hexa­valent molybdenum and tungsten that have hexa­gonal tungsten oxide (HTO) related [M₃XO₁₂]²⁻ (M = Mo, W; X = Se, Te) anionic frameworks with pyramidally coordinated Se⁴⁺ and Te⁴⁺ ions. The single-crystal X-ray structures were determined for all except for the A₂W₃SeO₁₂ (A = NH₄, Cs, Rb) compounds, which were synthesized in polycrystalline form by the hydro­thermal method; the structures of the (NH₄)₂W₃SeO₁₂ and Cs₂W₃SeO₁₂ compounds were determined by powder neutron diffraction (Harrison et al., 1995). K₂W₃TeO₁₂ has a centrosymmetric three-dimensional structure (Goodey et al., 2003), whereas all of the others exhibit a non-centrosymmetric two-dimensional structure and show SHG response. It is noteworthy that the tellurites were synthesized by both hydro­thermal and solid-state reactions, whereas the selenites were synthesized only by the hydro­thermal method.

Ag₂Mo₃SeO₁₂ (Ling & Albrecht-Schmitt 2007), Li₂Mo₃TeO₁₂ (Oh et al., 2018) and A₄Mo₆Te₂O₂₄·6H₂O (A = Rb, K) (Vidyavathy Balraj & Vidyasagar 1998) compounds are quaternary selenite and tellurites of molybdenum, whose [Mo₃XO₁₂]²⁻ (X = Se, Te) anionic framework structures are not related to HTO. They have centrosymmetric layered and zero-dimensional structures and contain pyramidally coordinated Se⁴⁺ and pyramidally and disphenoidally coordinated Te⁴⁺ ions.

In this context, the structural characterization of new and known quaternary A₂W₃SeO₁₂ (A = NH₄, Cs, Rb, K, Tl) selenites of tungsten(VI) by single-crystal X-ray diffraction was considered necessary for their complete structural study and, therefore, was undertaken. This report is concerned with crystal growth by solid-state reactions and structural characterization of the known compounds A₂W₃SeO₁₂ [A = NH₄ (1), Cs (2) and Rb (3)] and new compounds K₂W₃SeO₁₂ (4α) and Tl₂W₃SeO₁₂ (5).

2. Structural commentary

The structures of compounds 1–5 are of two types, which contain a hexa­gonal tungsten oxide (HTO) related [W₃SeO₁₂]²⁻ anionic framework. (NH₄)₂W₃SeO₁₂ (1), Cs₂W₃SeO₁₂ (2) and Rb₂W₃SeO₁₂ (3) crystallize in the P6₃ space group and have the structure of Cs₂W₃TeO₁₂ (Zhao et al., 2015). They contain ammonium/caesium/rubidium ions between non-centrosymmetric HTO-related [W₃SeO₁₂]²⁻ layers, which have only intra-layer type Se—O bonds. The absolute structure configuration of the rubidium compound (3) is the inverse of that of the ammonium (1) and caesium (2) compounds.

As an illustrative example, the structure of Rb₂W₃SeO₁₂ (3) is discussed. Its asymmetric unit content of Rb_2/3WTe_1/3O₄ has two, one, one and four crystallographically distinct rubidium, tungsten, selenium and oxygen atoms, respectively. The tungsten atom is octa­hedrally coordinated to the apical O1 and O2 atoms and two each of equatorial O3 and O4 atoms (Fig. 1). The WO₆ octa­hedron resides near the threefold rotation axis located at the Wyckoff site 2a and shares its two cis O3 equatorial oxygen atoms with two such octa­hedra to form a W₃O₁₅ moiety. Such trinuclear moieties are connected to one another through sharing of equatorial O4 atoms, forming a hexa­gonal–tungsten–oxide (HTO) layer of composition WO₄ or W₃O₁₂. In other words, the HTO layer of WO₄ is formed from the sharing of four equatorial O3 and O4 atoms of every WO₆ octa­hedron with four such octa­hedra. The HTO layer of WO₄ has three-ring holes made of either O3 or O4 atoms and six-ring holes made of alternating O3 and O4 atoms. The selenium atom resides on a threefold rotation axis located at the 2a site and has a pyramidal coordination of C_3V symmetry, with three equivalent Se—O1 bonds. Thus, only three-ring holes of O3 are capped on one side of the layer, by bonding of the selenium atom to apical O1 oxygen atoms, to give rise to an asymmetric (W₃SeO₁₂)²⁻ layer. These layers are stacked, as shown in Fig. 1, along the crystallographic c-axis direction in the ABAB… fashion because adjacent layers are rotated with respect to each other such that the six-ring hole of one layer is above the uncapped three-ring hole of the next layer. As the other apical oxygen O2 atoms are not bonded to selenium, the Se—O bonding is described as intra-layer bonding and, therefore, the structure is two-dimensional. The pyramidal SeO₃ moieties and the lone-pair of electrons of Se⁴⁺ are respectively parallel and perpendicular to the HTO layers of WO₄. The selenites 1–5 of the present study are found to contain the same staggered stacking of the HTO-related WO₄ layers.

Figure 1 Polyhedral representation of (left) the unit-cell structure viewed along the a axis and (right) a (W3SeO12)2− layer along with the Rb+ counter-cations, viewed along the c axis, of Rb2W3SeO12 (3). A W3O15 moiety with a pyramidal selenium atom is indicated by a dashed red line and the net dipole directions of the WO6 octa­hedra and pyramidal SeO3 are shown.

K₂W₃SeO₁₂ (β) was reported (Huang et al., 2014a,b) to be obtained under hydro­thermal conditions and found to contain similar non-centrosymmetric HTO-related [W₃SeO₁₂]²⁻ layers with intra-layer Se—O bonds. On the other hand, K₂W₃SeO₁₂ (4α) of the present study was prepared by solid-state reaction and is isostructural with the reported K₂W₃TeO₁₂ (Goodey et al., 2003). Its centrosymmetric, three-dimensional HTO-related [W₃SeO₁₂]²⁻ framework contains inter-layer Se—O bonds (Fig. 2) and its asymmetric unit has one formula unit. The three W1—W3 atoms are octa­hedrally coordinated to six apical O1–O6 and six equatorial O7–O12 oxygen atoms. The three WO₆ octa­hedra in the trinuclear W1W2W3O₁₅ moieties share equatorial O7–O9 oxygen atoms and these moieties are connected to one another through the other equatorial O10–O12 oxygen atoms to form the WO₄ layer. The Se atom forms inter­layer Se—O bonds, by bonding to the apical O7, O10 and O12 oxygen atoms of W1W2W3O₁₅ moieties of adjacent HTO layers (Fig. 2) and thus the [W₃SeO₁₂]²⁻ framework is three-dimensional in nature.

Figure 2 Polyhedral representation of (left) the unit-cell structure viewed along the −a axis and (right) a segment of the (W3SeO12)2− structure along with the K+ counter-cations, viewed along the −b axis, of K2W3SeO12 (4α). A W1W2W3O15 moiety with pyramidal selenium is indicated by a dashed red line and the net dipole directions of octa­hedral WO6 and pyramidal SeO3 are shown.

Tl₂W₃SeO₁₂ (5) has an ortho­rhom­bic unit cell with a_o = 11.5962 (10) Å, b_o = 12.7206 (5) Å and c_o = 7.2362 (9) Å. The structure refinements in the non-centrosymmetric Pna2₁ and centrosymmetric Pnam space groups led to the respective structure agreement factor values of 6.37% and 15.98%; the structure refinements were unsatisfactory, mostly due to X-ray absorption. Its single crystal X-ray structure solution model is found to be same as the three-dimensional structure of K₂W₃SeO₁₂ (4α) and its observed powder XRD pattern (Figure S1b in the supporting information) agrees reasonably with the one simulated on the basis of this model structure. Moreover, the powder XRD patterns and unit-cell parameters of these two compounds are similar. The ortho­rhom­bic unit-cell parameters of the thallium (5) compound are related to the monoclinic unit-cell parameters of the potassium (4α) compound as follows: a_o ≃ b_m, b_o ≃ c_m, c_o ≃ a_m and α_o = 90° ≃ β_m. The single-crystal X-ray data for the thallium compound (5) in the centrosymmetric P2₁/n space group, corresponding to the potassium compound (4α), led to the same structure model and a high value of 19.18% for the structure-agreement factor. It is inferred from these observations that the Tl₂W₃SeO₁₂ compound (5) has the same three-dimensional structure as K₂W₃SeO₁₂ (4α).

In the structurally characterized compounds 1–4α of the present study, the WO₆ octa­hedra have C₃ distortion as three W—O bonds are <1.9 Å long and their three trans W—O bonds are >1.9 Å long; the values of WO₆ intra­octa­hedral distortions (Halasyamani 2004), Δ_d, are calculated to be in the 0.73–0.86 range (Table S1). The Se⁴⁺ ions have pyramidal coordination. The W—O and Se—O bond-length values are in the 1.703 (17)–2.184 (9) Å and 1.695 (10)–1.739 (10) Å ranges, respectively. The ammonium and alkali metal ions are found to be six- to nine-coordinated (Figure S2), when the cut-off value of 3.6 Å is considered for N⋯O non-bonding distances and A—O bond lengths. The calculated values (Brese & O'Keeffe 1991) of bond-valence sums for W⁶⁺, Se⁴⁺ and monovalent alkali metal ions are in the 6.079–6.283, 3.807–3.975 and 0.060–1.275 ranges, respectively. The respective values of 3.210, 3.322 and 3.207 Å for the shortest inter­layer O⋯O non-bonding distances of compounds 1–3 with intra-layer Se—O bonds are significantly higher than the corresponding value of 2.563 Å for compound 4α with inter­layer Se—O bonds.

The net dipole moment values for the WO₆ and SeO₃ polyhedra were calculated by vector summation of the dipole moments (Maggard et al., 2003; Ok & Halasyamani 2005; Galy et al., 1975) of six W—O bonds and three Se—O bonds and found to be in the 0.79–1.85 D and 5.73–9.13 D ranges, respectively (Tables S1–S3). The net dipole for the WO₆ octa­hedron points towards the triangular face of three oxygen atoms with W—O bonds >1.9 Å long, whereas the net dipoles for the SeO₃ polyhedra point opposite to the lone pair of electrons of selenium. In compounds 1–3, as shown for Rb₂W₃SeO₁₂ (3) in Fig. 1, the intra-layer SeO₃ dipole is oriented along the c-axis direction and perpendicular to the HTO layer. For the WO₆ octa­hedra, the net dipole moment components along the a and b axes cancel one another, whereas the c-axis component is anti­parallel and additive to the net dipole moment of pyramidal SeO₃. In the case of centrosymmetric three-dimensional K₂W₃SeO₁₂ (4α), as shown in Fig. 2, the net dipole moments of the WO₆ and SeO₃ polyhedra macroscopically cancel one another and result in a zero net dipole moment.

The solid state UV–Visible absorption spectra (Fig. 3) of compounds 1–5 reveal that their band gap values are in the range 2.7–3.5 eV (Kubelka & Munk, 1931). The additional absorption edge observed for the Tl₂W₃SeO₁₂ compound (5) corresponds to band gap value of 2.0 eV. When compared to Cs₂W₃SeO₁₂ (2), the corresponding Cs₂W₃TeO₁₂ tellurite (Zhao et al., 2015) has a lower band gap of 2.89 eV.

Figure 3 Solid state UV–visible absorption spectra for the A2W3SeO12 [A = NH4 (1), Cs (2), Rb (3), K (4α) and Tl (5)] compounds.

Rb₂W₃SeO₁₂ (3), K₂W₃SeO₁₂ (4α) and Tl₂W₃SeO₁₂ (5) undergo thermal decompositions and give rise to endothermic peaks at ∼600, ∼575 and ∼575°C and their respective observed weight losses of 10.0%, 12.3% and 9.0% compare well with those calculated for the loss of SeO₂ (Figure S3). The other endothermic peaks at ∼850 and 750°C could not be assigned. It was reported (Harrison et al., 1995) that a similar thermal loss of SeO₂ occurs in a single step between 500 and 600°C for Cs₂W₃SeO₁₂ (2) and in two steps at 350 and 450°C for (NH₄)₂W₃SeO₁₂ (1). When compared to the tungsten selenites 1–5, analogous A₂W₃TeO₁₂ (A = K, Rb, Cs) tellurites of tungsten (Goodey et al., 2003; Zhao et al., 2015) and A₂Mo₃SeO₁₂ (A = Rb, Tl) selenites of molybdenum (Chang et al., 2010) undergo single-step thermal decomposition at higher and lower temperatures of >700 and 300°C, respectively.

3. Syntheses and crystallization

Cs₂CO₃ (Alfa Aesar), Rb₂CO₃ (Alfa Aesar), TlNO₃ (Sigma Aldrich), H₂WO₄ (Sigma Aldrich), SeO₂ (Sigma Aldrich), NH₄Cl (Sarabhai M Chemicals) of >99% purity, NH₄OH (Fischer Scientific) of 25% dilution, WO₃ and Tl₂WO₄ were used for the synthesis and crystal growth of compounds 1–5. WO₃ was obtained by heating H₂WO₄ in the open air. Tl₂WO₄ was prepared by heating a stoichiometric mixture of TlNO₃ and H₂WO₄. Teflon-lined stainless steel acid digestion vessels of 23 mL capacity were employed for the hydro­thermal reactions.

The reactants and their qu­anti­ties, the temperature and duration of heating and the yields of products for the synthesis and crystal growth of compounds 1–5 are presented in Table S4. The ammonium compound (1) was synthesized by the hydro­thermal method, with or without NH₄Cl as mineralizer. The other four compounds (2–5) were obtained by solid-state reactions. The reactant mixtures were heated first in the open air and later in evacuated sealed silica ampoules. After the reaction, the solid product contents were washed with water to dissolve away the excess SeO₂.

The hydro­thermal and solid-state synthetic methods enabled the growth and isolation of single crystals of compounds 1–5. The utilization of excess SeO₂ as flux in the novel solid-state synthetic procedure facilitated the growth of single crystals of compounds 2–5. The powder XRD patterns of compounds 1–5 are presented in Figures S1a and S1b. (NH₄)₂W₃SeO₁₂ (1), Rb₂W₃SeO₁₂ (3) and Tl₂W₃SeO₁₂ (5) were obtained as homogeneous phases, as their observed powder XRD patterns compare reasonably well with the simulated ones. The powder XRD patterns of Cs₂W₃SeO₁₂ (2), Rb₂W₃SeO₁₂ (3) and K₂W₃SeO₁₂ (4α) contained two or three additional reflections of <10% intensity due to WO₃ or an unidentified phase; however, the homogeneous polycrystalline sample of Rb₂W₃SeO₁₂ (3) could be obtained (Figure S1b), under a different set of solid-state synthetic conditions mentioned in Table S4. Cs₂W₃SeO₁₂ (2) was prepared in polycrystalline form by the reported hydro­thermal method (Harrison et al., 1995). It is evident from the scanning electron micrographs (Figure S4) that crystallites of compounds 1 and 2 have a hexa­gonal prism shape and compounds 3–5 have block-shaped morphologies. The EDXA analyses confirmed the expected ratios of metal contents for all compounds 1–5.

4. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 1. The crystals of the ammonium (1) and rubidium (3) compounds are twinned by merohedry (Spek 2020) by the [−1 0 0 1 1 0 0 0 − 1] and [1 0 0 − 1 −1 0 0 0 − 1] twin laws and their twinned lattices are generated through twofold rotation of the primary lattices about the [120] direction and the b axis, respectively. The crystal of the potassium (4α) compound is twinned by pseudo-merohedry (Spek 2020) by the twin law [−1 0 0 0 − 1 0 0 0 1] and the twinned lattice is generated through twofold rotation of the primary lattice about the c axis, as the value of the β angle of its monoclinic system is very close to 90°. The respective values of refined batch scale factor for the ammonium (1), rubidium (3) and potassium (4α) compounds are 0.029, 0.192 and 0.385. The hydrogen atoms of the NH₄⁺ ions in the ammonium compound (1) were not located in the difference-Fourier maps but are included in the formula. The final difference-Fourier maps did not show any chemically significant features and the Fourier difference peaks with an electron density of >1 e Å⁻³ were found to be ghosts. No reasonable structure solutions and refinements in the centrosymmetric P6₃/m space group were found for compounds 1–3.

Table 1 Experimental details   1 2 3 4 Crystal data Chemical formula (NH4)2W3SeO12 Cs2W3SeO12 Rb2W3SeO12 K2W3SeO12 Mr 858.59 1088.33 993.40 900.66 Crystal system, space group Hexagonal, P63 Hexagonal, P63 Hexagonal, P63 Monoclinic, P21/n Temperature (K) 297 293 293 293 a, b, c (Å) 7.2303 (3), 7.2303 (3), 12.1491 (5) 7.2580 (3), 7.2580 (3), 12.5291 (5) 7.2380 (1), 7.2380 (1), 12.1115 (3) 7.2310 (2), 11.4863 (4), 12.6486 (4) α, β, γ (°) 90, 90, 120 90, 90, 120 90, 90, 120 90, 90.096 (2), 90 V (Å3) 550.03 (5) 571.59 (5) 549.50 (2) 1050.56 (6) Z 2 2 2 4 Radiation type Mo Kα Mo Kα Mo Kα Mo Kα μ (mm−1) 34.67 39.63 43.49 37.09 Crystal size (mm) 0.10 × 0.10 × 0.05 0.10 × 0.08 × 0.05 0.10 × 0.05 × 0.05 0.08 × 0.05 × 0.02   Data collection Diffractometer Bruker APEXII CCD Bruker APEXII CCD Bruker APEXII CCD Bruker APEXII CCD Absorption correction Multi-scan (SADABS; Krause et al., 2015) Multi-scan (SADABS; Krause et al., 2015) Multi-scan (SADABS; Krause et al., 2015) Multi-scan (SADABS; Krause et al., 2015) Tmin, Tmax 0.129, 0.276 0.110, 0.242 0.098, 0.220 0.155, 0.524 No. of measured, independent and observed [I > 2σ(I)] reflections 14419, 1079, 1069 2825, 831, 730 3497, 675, 654 26562, 4026, 3456 Rint 0.049 0.058 0.033 0.073 (sin θ/λ)max (Å−1) 0.702 0.643 0.666 0.770   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.023, 0.052, 1.27 0.029, 0.054, 1.02 0.018, 0.033, 1.06 0.032, 0.105, 1.15 No. of reflections 1079 831 675 4026 No. of parameters 57 56 57 165 No. of restraints 1 13 7 24 H-atom treatment H-atom parameters not defined – – – Δρmax, Δρmin (e Å−3) 2.63, −2.37 1.90, −1.65 0.90, −1.14 3.94, −3.11 Absolute structure Flack x determined using 492 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013) Flack x determined using 297 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013) Flack x determined using 182 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013)   Absolute structure parameter 0.015 (13) 0.00 (3) −0.08 (3) – Computer programs: APEX2 and SAINT (Bruker, 2004), SHELXT (Sheldrick, 2015a), SHELXL2013 (Sheldrick, 2015b), SHELXL (Sheldrick, 2015b), ORTEP-3 for Windows (Farrugia, 2012), DIAMOND (Pennington, 1999) and SHELXL97 (Sheldrick, 2008).

The powder X-ray diffraction (XRD) patterns of compounds 1–5 were recorded on a Bruker D8 Advanced powder X-ray diffractometer using Cu Kα (λ = 1.5418 Å) radiation. The monophasic nature of each of these compounds was verified by comparing their powder XRD patterns with those simulated, using Mercury (Macrae et al., 2020), on the basis of their single crystal X-ray structures.