1. Chemical context

The peculiar feature of the crystal chemistry of oxotellurates(IV) (Christy et al., 2016) is the presence of the 5s² lone electron pair, denoted E. In the majority of cases, the lone electron pair E is stereochemically active, making oxotellurates(IV) inter­esting for crystal engineering, e.g. in terms of the synthesis of compounds with non-centrosymmetric structures or structures with polar directions. Next to the influence of the (metal) cation on the physico-chemical characteristics of oxotellurates(IV), physical and underlying structural properties of such compounds can also be varied by incorporation of other oxoanions into the oxotellurate(IV) framework, e.g. by p-block oxoanions such as nitrate (Stöger & Weil, 2013) or selen­ate (Weil & Shirkanlou, 2015), or by d-block oxoanions such as vanadate (Weil, 2015).

In this context we attempted the hydro­thermal synthesis of new oxotellurate phases in the system Sr–Te–Se–O–(H). In comparison with typical solid-state reactions using open crucibles under atmospheric conditions, this method is more feasible because Te^IV then tends not to be oxidized or to be evaporated during the reaction process. However, a clear disadvantage of the hydro­thermal method is the high(er) number of adjustable parameters (pressure, concentration, temperature, time, filling degree, solvent etc), which often makes the products of these experiments difficult to predict or even to reproduce, accompanied by formation of several solid phases in one batch. This was also the case for the present study. Instead of a strontium oxoselenatotellurate, several oxotellurate phases were obtained without incorporation of selenium. Amongst these phases, the title compound, Sr₅Te₄O₁₂(OH)₂, a hitherto unknown strontium oxotellurate, was isolated and structurally determined by single crystal X-ray diffraction.

2. Structural commentary

The asymmetric unit of Sr₅Te₄O₁₂(OH)₂ comprises three Sr, two Te and seven O atoms (H atoms were not included in the final model, see Section 5 and discussion below). Except one Sr atom (Sr2) that is located on a twofold rotation axis, all atoms are in general positions.

The coordination numbers of the Sr atoms are 7 (for Sr1 and Sr3) and 8 (for Sr2) if Sr—O distances < 3.0 Å are considered as relevant for the first coordination sphere. The corresponding polyhedra are considerably distorted, with Sr—O bond lengths ranging from 2.393 (11) to 2.960 (11) Å (Table 1) and might be described as monocapped octa­hedra for Sr1 and Sr3, and as a bicapped trigonal prism for Sr2. The SrO₈ and the two SrO₇ polyhedra share corners and edges, thereby constructing a three-dimensional framework structure encapsulating channels that propagate along [010]. Each of the two Te atoms connect to the outer oxygen atoms of the framework in a very similar trigonal-prismatic configuration (Table 1), with the 5s² lone electron pair E being stereochemically active, i.e. pointing towards the empty space of the channels (Fig. 1). The channel diameter (without contribution of the lone pairs) is ≃ 4 Å. Te—O bond lengths [1.865 (11)–1.890 (12) Å for Te1 and 1.858 (11)–1.886 (11) Å for Te2] and O—Te—O angles [98.0 (5)–100.3 (5)° for Te1 and 98.8 (5)—101.1 (5)° for Te2] are typical for oxotellurate(IV) anions with three oxygen partners (Christy et al., 2016).

Table 1 Selected geometric parameters (Å, °) Sr1—O7 2.430 (12) Sr3—O2 2.507 (11) Sr1—O5i 2.476 (12) Sr3—O4v 2.517 (11) Sr1—O1ii 2.593 (12) Sr3—O6i 2.536 (11) Sr1—O3 2.596 (11) Sr3—O6vi 2.590 (12) Sr1—O2iii 2.616 (12) Sr3—O4vii 2.644 (11) Sr1—O7iii 2.700 (11) Sr3—O1viii 2.666 (11) Sr1—O2 2.852 (12) Te1—O6 1.865 (11) Sr2—O3 2.510 (11) Te1—O2 1.871 (11) Sr2—O1iv 2.624 (12) Te1—O5 1.890 (12) Sr2—O5 2.633 (12) Te2—O4 1.858 (11) Sr2—O7 2.960 (11) Te2—O3 1.882 (11) Sr3—O7iii 2.393 (11) Te2—O1 1.886 (11)         O6—Te1—O2 99.4 (4) O4—Te2—O3 101.1 (5) O6—Te1—O5 100.3 (5) O4—Te2—O1 100.3 (5) O2—Te1—O5 98.0 (5) O3—Te2—O1 98.8 (5) Symmetry codes: (i) x, y-1, z; (ii) -x, y, -z+1; (iii) ; (iv) -x, y+1, -z+1; (v) ; (vi) ; (vii) -x, y, -z; (viii) .

Figure 1 Projection of the crystal structure of Sr5Te4O12(OH)2 along [010], with displacement ellipsoids drawn at the 74% probability level. The trigonal–pyramidal TeO3 groups are given in red; the O atom representing the OH group is given in yellow, all other O atoms are colourless.

Bond-valence calculations (Brown, 2002) clearly reveal the presence of an OH group for atom O7 (Table 2), also required by charge neutrality. Atom O7 is bonded to four Sr atoms (Table 1, Fig. 1) and has also four possible oxygen acceptor atoms for hydrogen bonding of medium to weak strength (Table 3). The situation of four possible acceptor atoms is displayed in Fig. 2 and makes it appear likely that the corres­ponding H atom of the OH group is positionally disordered and thus could not be located during the present study.

Table 2 Results of the bond-valance-sum (BVS) analysis Atom BVS Δ to expected value Sr1 2.07 0.07 Sr2 1.91 0.09 Sr3 2.23 0.23 Te1 3.94 0.06 Te2 3.93 0.07 O1 2.04 0.04 O2 2.08 0.08 O3 1.91 0.09 O4 1.96 0.04 O5 1.89 0.11 O6 1.95 0.05 O7 1.21 0.79 BVS parameters of Brown & Altermatt (1985) were used for all bonds.

Table 3 Hydrogen-bond geometry (Å) D—H⋯A D⋯A O7⋯O5 2.808 (12) O7⋯O2 2.893 (12) O7⋯O2ix 2.991 (11) O7⋯O1iv 3.063 (11) Symmetry codes: (iv) -x, y+1, -z+1; (ix) .

Figure 2 The vicinity of the OH group emphasizing the different possibilities for O⋯O hydrogen bonding (green lines). Sr—(OH) bonds have been omitted for clarity. Symmetry operators refer to those of Table 3; displacement ellipsoids are the same as in Fig. 1.

In the sense of a crystal-chemically more detailed formula, the title compound may alternatively be formulated as 4SrTeO₃·Sr(OH)₂ and represents the first basic strontium oxotellurate(IV), viz. with the presence of an OH functionality. In comparison with the other strontium oxotellurates(IV) compiled in Section 3, all Sr—O and Te—O lengths are in similar ranges.

3. Database survey

In the Inorganic Crystal Structure Database (ICSD, 2016) structural data for the following hydrous or anhydrous strontium oxotellurate(IV) phases have been deposited: SrTe₅O₁₁ (Burckhardt & Trömel, 1983), Sr₃Te₄O₁₁ (Dytyatyev & Dolgikh, 1999), various polymorphs of SrTeO₃ (Dityatiev et al., 2006; Zavodnik et al., 2007a,b,c, 2008; Stöger et al., 2011), SrTe₃O₈ (Barrier et al., 2006; Weil & Stöger, 2007) and SrTeO₃(H₂O) (Stöger et al., 2011). Additionally, in the Inter­national Centre for Diffraction Data PDF-4 database (ICDD, 2015) diffraction data for the following phases are compiled: Sr₂Te₃O₈ (Elerman & Koçak, 1986), SrTe₂O₅ (Redman et al., 1970; Gorbenko et al., 1983) and a high-temperature phase of the latter (Külcü et al., 1984).

4. Synthesis and crystallization

For the hydro­thermal experiment, a Teflon container was filled with 0.0733 g of strontium oxide, 0.1529 g of tellurium dioxide and 0.032 ml of selenic acid (conc.; 96 wt%), corresponding to the stoichiometric ratio 3:2:1. To this mixture 10 ml water were added to about three-fourth of the container volume. The container was then sealed with a Teflon lid and loaded into a stainless steel autoclave and then heated at autogenous pressure in an oven at 403 K for one week. After the reaction time, the autoclave was allowed to cool down to room temperature over six h. The formed solid product was filtered off and washed with water and ethanol. Inspection under a polarizing microscope revealed a phase mixture with different crystal forms clearly discernible. According to X-ray powder diffraction of the bulk material, the following phases could be identified: α-TeO₂ (Lindqvist, 1968), SrTe₂O₅ (Redman et al., 1970), SrTe₃O₈ (Barrier et al., 2006; Weil & Stöger, 2007) and SrTe₅O₁₁ (Burckhardt & Trömel, 1983). Solid reaction products containing Se-phases were not detected. Platy Sr₅Te₄O₁₂(OH)₂ crystals were present in only minor amounts, and were manually separated for structure determination from the other solid products.

5. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 4. Some of the O atoms showed physically unreasonable behaviour when refined with anisotropic displacement parameters. Hence, for the final model all O atoms were refined with individual isotropic displacement parameters. The H atom of the OH group (or positionally disordered parts) could not be located and thus was not included in the model. Twinning by inversion was also taken into account, with a contribution of the minor twin component of about 6%. The maximum and minimum remaining electron densities are found 2.34 and 0.96 Å, respectively, from Sr3.

Table 4 Experimental details Crystal data Chemical formula Sr5Te4O12(OH)2 Mr 1174.52 Crystal system, space group Monoclinic, C2 Temperature (K) 295 a, b, c (Å) 16.0785 (10), 5.7927 (5), 8.9262 (7) β (°) 107.542 (4) V (Å3) 792.71 (11) Z 2 Radiation type Mo Kα μ (mm−1) 23.99 Crystal size (mm) 0.18 × 0.06 × 0.01   Data collection Diffractometer Bruker APEXII CCD Absorption correction Multi-scan (SADABS; Bruker, 2012) Tmin, Tmax 0.099, 0.795 No. of measured, independent and observed [I > 2σ(I)] reflections 12913, 1914, 1319 Rint 0.088 (sin θ/λ)max (Å−1) 0.660   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.042, 0.085, 1.02 No. of reflections 1914 No. of parameters 71 No. of restraints 1 H-atom treatment H-atom parameters not defined Δρmax, Δρmin (e Å−3) 2.31, −1.78 Absolute structure Refined as an inversion twin Absolute structure parameter 0.058 (18) Computer programs: APEX2 and SAINT (Bruker, 2012), SHELXS97 (Sheldrick, 2008), SHELXL2014 (Sheldrick, 2015), ATOMS (Dowty, 2006) and publCIF (Westrip, 2010).