1. Chemical context

Na₂MoO₄ and Na₂WO₄ are unusual amongst the alkali metal mono-molybdates and mono-tungstates in being highly soluble in water and forming polyhydrated crystals. Additionally, sodium apparently plays a significant role in the solvation of other alkali metal ions to form a range of double molybdate and tungstate hydrates (Klevtsova et al., 1990; Klevtsov et al., 1997; Mirzoev et al., 2010), for example, Na₃K(MoO₄)₂·9H₂O. Both dihydrate and deca­hydrate varieties of the two title compounds are known, their solubilities as a function of temperature being well characterised (Funk, 1900; Zhilova et al., 2008). The structures of the deca­hydrates have not yet been reported, although I have established that they are not isotypic with the sodium sulfate analogue, Na₂SO₄·10H₂O, as had hitherto been thought.

The dihydrates have been the subject of extensive crystallographic studies, from descriptions of their density, habit and measurements of inter­facial angles (Svanberg & Struve, 1848; Zenker, 1853; Rammelsberg, 1855; Marignac, 1863; Delafontaine, 1865; Ullik, 1867; Clarke, 1877; Zambonini, 1923), through to determination of absolute unit-cell parameters (Pistorius & Sharp, 1961), and subsequent solution and refinement of their structures (Mitra & Verma, 1969; Okada et al., 1974; Matsumoto et al., 1975; Atovmyan & D'yachenko, 1969; Capitelli et al., 2006; Farrugia, 2007). However, the presence of heavy atoms in these materials makes it impossible to achieve a uniform precision on all structural parameters using X-rays, and even with single-crystal methods that purport to identify hydrogen positions there may be significant inaccuracies. Such problems are minimised using a neutron radiation probe since the coherent neutron scattering lengths of the constituent elements differ by less than a factor of two, being 6.715 fm for Mo, 4.86 fm for W, 3.63 fm for Na, 5.803 fm for O, and 6.67 fm for ²D (Sears, 1992). Thus one can locate accurately all of the light atoms and obtain a uniform level of precision on their coordinates and displacement parameters. Since the incoherent neutron scattering cross section of ¹H is large (80.3 barns) it is usual to prepare perdeuterated specimens whenever possible (the incoherent cross section of ²D being only 2.1 barns) as this optimises the coherent Bragg scattering signal above the background, reducing the counting times required for a high-precision structure refinement from many days to a matter of hours on the instrument used for these measurements. These data were therefore measured using Na₂MoO₄·2D₂O and Na₂WO₄·2D₂O samples.

The occurrence of polyhydrated forms of both Na₂MoO₄ and Na₂WO₄ suggests that both would be excellent candidates for the formation of hydrogen-bonded complexes with water-soluble organics, such as amino acids, producing metal-organic crystals with potentially useful optical properties (cf., glycine lithium molybdate; Fleck et al., 2006). High-pressure polymorphs of Na₂MoO₄·2H₂O and Na₂WO₄·2H₂O are indicated from Raman scattering studies (Luz-Lima et al., 2010; Saraiva et al., 2013). Characterising the structures and properties of the title compounds provides an essential foundation on which to build future studies of the high-pressure phases, of the as-yet incomplete deca­hydrate structures and any related organic-bearing hydrates.

2. Structural commentary

Na₂MoO₄·2H₂O and Na₂WO₄·2H₂O are isotypic, crystallizing in the ortho­rhom­bic space group Pbca; all atoms occupy general positions (Wyckoff sites 8c). Note that the atom labelling scheme and space-group setting used here follows Farrugia (2007); consequently there are some differences with respect to other literature sources, although equivalent contacts are referred to in Table 1 and Table 2. The X⁶⁺ ions (X = Mo, W) are tetra­hedrally coordinated by O²⁻, the Mo—O and W—O bond lengths varying slightly according to the type of coordination adopted by a particular apex: O1 and O4 are each coordinated to Na⁺ and each also accepts two hydrogen bonds; O2 is coordinated to three Na⁺ ions and O3 is coordinated to two Na⁺ ions (Fig. 1). In both title compounds, X–O1 and X–O4 are the longest contacts and X–O3 is the shortest contact in the tetra­hedral oxyanion. The mean Mo—O and W—O bond lengths are in good agreement with those found in the anhydrous crystals (Fortes, 2015). Furthermore, each of the absolute Mo—O bond lengths are identical (within error) to those found by Capitelli et al. (2006); the agreement in W—O bond lengths with Farrugia (2007) is marginally poorer.

Table 1 Comparison of the X—O (X = Mo, W) and Na—O bond lengths (Å) in Na2MoO4·2D2O and Na2WO4·2D2O with those of the protonated isotopologues reported in the literature   Na2MoO4·2D2O Na2MoO4·2H2O Na2WO4·2D2O Na2WO4·2H2O   This work Capitelli et al. (2006) This work Farrugia (2007) X—O1 1.773 (2) 1.772 (1) 1.785 (2) 1.776 (3) X—O2 1.764 (1) 1.767 (1) 1.778 (2) 1.778 (3) X—O3 1.750 (2) 1.751 (1) 1.766 (2) 1.761 (3) X—O4 1.776 (2) 1.778 (1) 1.783 (2) 1.787 (3) Mean X—O 1.766 1.767 1.778 1.776           Na1—O2 2.437 (3) 2.446 (2) 2.433 (2) 2.442 (3) Na1—O2(i) 2.417 (3) 2.419 (2) 2.412 (3) 2.416 (3) Na1—O3(ii) 2.482 (3) 2.481 (2) 2.479 (3) 2.480 (3) Na1—O4(iii) 2.410 (3) 2.395 (2) 2.399 (2) 2.388 (3) Na1—O5 2.476 (3) 2.456 (2) 2.479 (3) 2.464 (4) Na1—O6 2.426 (3) 2.423 (2) 2.443 (3) 2.433 (3) Mean Na1—O 2.441 2.437 2.441 2.437           Na2—O1iv 2.312 (3) 2.319 (2) 2.320 (2) 2.323 (3) Na2—O2 2.363 (3) 2.354 (2) 2.355 (2) 2.346 (3) Na2—O3v 2.339 (3) 2.341 (2) 2.328 (2) 2.331 (3) Na2—O5 2.415 (3) 2.403 (2) 2.409 (3) 2.396 (3) Na2—O6vi 2.305 (3) 2.300 (2) 2.311 (2) 2.304 (3) Mean Na2—O 2.347 2.343 2.345 2.340 Symmetry codes: (i) 1 − x, 1 − y, 1 − z; (ii) − + x,  − y, 1 − z; (iii)  − x, − + y, z; (iv)  + x,  − y, 1 − z; (v)  − x, − + y, z; (vi)  + x, y,  − z.

Table 2 Comparison of the water mol­ecule and hydrogen bond geometry (Å, °) in Na2MoO4·2D2O and Na2WO4·2D2O with the protonated isotopologues as reported in the literature. Note the inclusion of the contact O5–D51···O3, which forms the longer `branch' of Farrugia's proposed bifurcated hydrogen bond   Na2MoO4·2D2O Na2MoO4·2H2O Na2WO4·2D2O Na2WO4·2H2O   This work Capitelli et al. (2006) This work Farrugia (2007) O5—D51 0.977 (2) 0.68 (3) 0.970 (2) 0.86 (3) O5—D52 0.966 (2) 0.76 (3) 0.959 (2) 0.86 (3) D51—O5—D52 106.0 (2) 98 (4) 106.0 (2) 100 (5) D51···O1(i) 1.874 (2) 2.16 (3) 1.873 (2) 2.09 (4) O5—D51···O1(i) 167.9 (2) 167 (4) 168.2 (2) 145 (6) D51···O3(ii) – – – 2.70 (6) O5—D51···O3(ii) – – – 122 (5) D52···O4(ii) 1.846 (3) 2.07 (3) 1.863 (2) 1.98 (3) O5—D52···O4(ii) 171.2 (2) 176 (3) 170.9 (2) 174 (6)           O6—D61 0.972 (2) 0.83 (3) 0.968 (2) 0.86 (3) O6—D62 0.972 (2) 0.71 (3) 0.966 (2) 0.86 (3) D61—O6—D62 103.0 (2) 105 (3) 103.2 (2) 95 (5) D61···O1 1.816 (2) 2.01 (3) 1.834 (2) 1.95 (3) O6—D61···O1 167.0 (2) 167 (3) 167.0 (2) 167 (6) D62···O4(iii) 1.868 (4) 2.08 (3) 1.876 (2) 2.02 (4) O6—D62···O4(iii) 168.7 (2) 170 (3) 168.7 (2) 159 (6) Symmetry codes: (i) 1 − x, 1 − y, 1 − z; (ii) 1 − x, − + y,  − z; (iii) − + x,  − y, 1 − z.

Figure 1 First and second coordination shell of Mo6+/W6+ in the title compounds, revealing differences in the environment of each apical O2− that are responsible for the variations in Mo–O and W–O bond lengths. Anisotropic displacement ellipsoids are drawn at the 50% probability level. [Symmetry codes: (i) 1 − x, 1 − y, 1 − z; (ii)  + x,  − y, 1 − z; (iii) − + x,  − y, 1 − z; (iv)  − x,  + y, z; (v)  − x,  + y, z; (vi) 1 − x,  + y, 1.5 − z.]

The Na⁺ ions occupy two inequivalent sites: in one, Na⁺ is six-fold coordinated by two water mol­ecules and four XO₄²⁻ oxygen atoms, yielding an octa­hedral arrangement; in the second, Na⁺ is five-fold coordinated by two water mol­ecules and three XO₄²⁻ oxygen atoms, yielding a square-pyramidal arrangement. These two polyhedra share a common edge (O2–O5) and are connected, moreover, with their inversion-centre-related neighbours along three other shared edges to form a cluster (Fig. 2a). The clusters corner-share via O6 to create a `slab' parallel to (010) (Fig. 2b). The mean Na—O bond lengths are statistically identical in Na₂MoO₄·2D₂O and Na₂WO₄·2D₂O being ∼1.6% longer in the NaO₆ octa­hedra and ∼2.3% shorter in the NaO₅ polyhedra than Na—O bonds in the anhydrous crystals (Fortes, 2015). The agreement in Na—O bond lengths with the X-ray single crystal studies of Capitelli et al. (2006) and Farrugia (2007) is very good. Overall, the agreement in bond lengths and angles for the two independently refined data sets is excellent (Tables 1 and 2).

Figure 2 (a) Arrangement of NaOx polyhedra into edge-sharing clusters comprised of two Na1O6 octa­hedra and two Na2O5 square pyramids; (b) Arrangement of the clusters shown in (a) by corner sharing to form `slabs' parallel (010). Ellipsoids are drawn at the 50% probability level. [Symmetry codes: (i) 1 − x, 1 − y, 1 − z; (ii)  + x,  − y, 1 − z; (iii) − + x,  − y, 1 − z; (iv)  − x, − + y, z; (v)  + x, y,  − z; (vi)  − x, 1 − y,  + z; (vii)  − x, − + y, z.]

Although it is more usual to find Na⁺ in octa­hedral coordination, there are abundant examples of Na⁺ in five-fold coordination, including instances where the NaO₅ polyhedron adopts a square-pyramidal arrangement (Beurskens & Jeffrey, 1961; Císařová; et al., 2001; Sharma et al., 2005; Smith & Wermuth, 2014; Aksenov et al., 2014) or the alternative trigonal-bipyramidal arrangement (Mereiter, 2013; Smith, 2013). A similar combination of NaO₆ and NaO₅ polyhedra to that found in the title compounds occurs in the closely-related hydrates Na₂CrO₄·1.5H₂O and Na₂SeO₄·1.5H₂O (Kahlenberg, 2012; Weil & Bonneau, 2014). The two water mol­ecules form hydrogen-bonded chains between the O1 and O4 atoms of the tetra­hedral oxyanions; O5-related chains extend along [001] and O6-related chains crosslink them in a staggered fashion along [100]. Fig. 3(a) and 3(b) depict the spatial relationship between this `net' of water linked tetra­hedra and the adjacent `slab' of corner-linked Na—O polyhedral clusters. The layers shown in Fig. 3(b) alternate to create the three-dimensional structure and are no doubt responsible for the macro-scale platy habit of the crystals.

Figure 3 (a) View down the b axis of the network of water-linked tetra­hedral oxyanions; chains linked by O5 extend along [001] whereas crosslinkages through O6 are staggered along [100]. (b) View of the same structure along the c axis. Ellipsoids are drawn at the 50% probability level. [Symmetry codes: (i) 1 − x, 1 − y, 1 − z; (ii) 1 − x,  + y,  − z; (iii)  + x,  − y, 1 − z; (iv)  + x, y,  − z; (v) x,  − y, − + z; (vi) x,  − y,  + z.]

There are no significant differences in the hydrogen bond geometries of the molybdate or tungstate crystals. The most recent X-ray single-crystal diffraction study of Na₂WO₄·2H₂O (Farrugia, 2007) implied that one of the water mol­ecules (O5) was involved in a weaker three-centred inter­action, although a similarly recent measurement of Na₂MoO₄·2H₂O (Capitelli et al., 2006) identified a `normal' linear two-centred inter­action for this bond. This work, using neutrons, has been able to accurately and precisely characterise the hydrogen bond geometry, showing that the latter is true for both structures; there is no bifurcated bond and all hydrogen-bonded inter­actions are of the linear two-centred variety. Presumably the error in Farrugia's analysis arose due to the substantial absorption correction required (μ = 18.7 mm⁻¹) for an accurate structure refinement from X-ray single-crystal data.

Raman spectra of Na₂MoO₄·2H₂O and Na₂MoO₄·2D₂O were first reported by Mahadevan Pillai et al. (1997); subsequently, Luz-Lima et al. (2010) and Saraiva et al. (2013) published the Raman spectra of Na₂MoO₄·2H₂O and Na₂WO₄·2H₂O as a function of temperature (13–300 K) and as a function of hydro­static pressure (to 5 GPa). Both compounds exhibit evidence of a `conformational change' on cooling through 120 K: the molybdate appears to undergo two high-pressure phase transitions, one at 3 GPa and the second at 4 GPa; the tungstate apparently undergoes a high-pressure phase transition at 3.9 GPa. The Raman spectra reported here (Figs. 4 and 5 and Supporting information) agree well with data in the literature (Table 3). The large blue-shifts in the inter­nal vibrational frequencies of the deuterated water mol­ecule are similar to the square root of the D:H mass ratio; the small blue-shifts of most of the inter­nal modes of the tetra­hedral oxyanions are consistent with stronger hydrogen bonding in the deuterated species, as expected (cf. Scheiner & Čuma, 1996; Soper & Benmore, 2008).

Table 3 Comparison of the inter­nal vibrational mode frequencies (cm−1) in fully protonated and 90 mol % deuterated isotopologues of Na2MoO4·2H2O and Na2WO4·2H2O with literature data   Na2MoO4·2H2O     Na2WO4·2H2O       This work (1H) This work (2D) Busey & Keller (1964) This work (1H) This work (2D) Busey & Keller (1964) ν2 (XO42−) 279 271 285 276 269 276   319 315 325 324 321 325   335 331   330 331   ν4 (XO42−) 359 358   358 355   ν3 (XO42−) 804 801 805 804 802 808   833 826 836 836 831 838   842 840 843   840   ν1 (XO42−)       891 889 893   894 894 897 929 928 931

Figure 4 Raman spectra of Na2MoO4·2H2O and Na2MoO4·2D2O in the range 200–3900 cm−1. Band positions and vibrational assignments are indicated (see also Table 3). Vertical scales show intensities relative to ν1 (XO42−).

Figure 5 Raman spectra of Na2WO4·2H2O and Na2WO4·2D2O in the range 200–3900 cm−1. Band positions and vibrational assignments are indicated (see also Table 3). Vertical scales show intensities relative to ν1 (XO42−).

3. Synthesis and crystallization

Coarse polycrystalline powders of Na₂MoO₄·2H₂O (Sigma–Aldrich M1003 > 99.5%) and Na₂WO₄·2H₂O (Sigma–Aldrich 14304 > 99%) were dehydrated by drying at 673 K in air. The resulting anhydrous materials were characterised by Raman spectroscopy, X-ray and neutron powder diffraction (Fortes, 2015). This material was dissolved in D₂O (Aldrich 151882, 99.9 atom% D) and twice recrystallized by gentle evaporation at 323 K. The molybdate crystallised with a coarse platy habit whereas the tungstate was deposited as a finer-grained material. Once the supernatant liquid was deca­nted, the residue was air dried on filter paper and then ground to a fine powder with an agate pestle and mortar. The powders were loaded into standard vanadium sample-holder tubes of inter­nal diameter 11 mm to a depth not less than 20 mm (this being the vertical neutron beam dimension at the sample position). Accurate volumes and masses were determined after the diffraction measurements were complete and used to correct the data for self-shielding. The level of deuteration was determined by Raman spectroscopy (see below) to be ∼91% for both compounds.

Raman spectra were acquired with a B&WTek i-Raman plus portable spectrometer; this device uses a 532 nm laser (37 mW power at the fiber-optic probe tip) to stimulate Raman scattering, which is measured in the range 170–4000 cm⁻¹ with a spectral resolution of 3 cm⁻¹. Data were collected for 600 sec at 17 mW for Na₂MoO₄·2H₂O (as bought), 180 sec at 37 mW for Na₂MoO₄·2D₂O, 300 sec at 17 mW for Na₂WO₄·2H₂O (as bought) and 220 sec at 37 mW for Na₂WO₄·2D₂O; after summation, the background was removed and peaks fitted using Pseudo-Voigt functions in OriginPro (OriginLab, Northampton MA). These data are provided as an electronic supplement in the form of an ASCII file. Small qu­anti­ties of ordinary hydrogen were found to be present in both specimens, the proportion being determined by the ratio of the areas under the ν₁/ν₃ (H₂O) bands after normalisation relative to the height of the strong ν₁ (XO₄²⁻) band. The molar abundance of ¹H was used to correct the diffraction data for absorption (see below) and to ensure accurate refinement of the structure (see Refinement).

Time-of-flight neutron diffraction patterns were collected at 295 K using the High Resolution Powder Diffractometer, HRPD (Ibberson, 2009), at the ISIS spallation neutron source, Harwell Campus, Oxfordshire, UK. Data were acquired in the range of neutron flight times from 30–130 msec (equivalent to neutron wavelengths of 1.24–5.36 Å) for 15.17 hr from the molybdate and 14.40 hr from the tungstate, equivalent to 615 and 590 µAhr of integrated proton beam current, respectively. These data sets were normalized to the incident spectrum and corrected for detector efficiency by reference to a V:Nb null-scattering standard and then subsequently corrected for the sample-specific and wavelength-dependent self-shielding using Mantid (Arnold et al., 2014: Mantid, 2013). In the case of the molybdate, the number density of the specimen was determined to be 3.28 mol nm⁻³, with a scattering cross section, allowing for the water being 9.1 mol % ¹H, σ_scatt = 93.81 b and an absorption cross section, σ_abs = 3.66 b; for the tungstate, the number density was 3.01 mol nm⁻³, the scattering cross section, allowing for the water being 8.6 mol % ¹H, σ_scatt = 94.19 b and σ_abs = 19.48 b. Diffraction data were exported in GSAS format and analysed with the GSAS/Expgui Rietveld package (Larsen & Von Dreele, 2000: Toby, 2001). The fitted diffraction data are shown in Figs. 6 and 7.

Figure 6 Neutron powder diffraction data for Na2MoO4·2D2O; red points are the observations, the green line is the calculated profile and the pink line beneath the diffraction pattern represents Obs−Calc. Vertical black tick marks report the expected positions of the Bragg peaks. The inset shows the data measured at short flight times (i.e. small d-spacings).

Figure 7 Neutron powder diffraction data for Na2WO4·2D2O; red points are the observations, the green line is the calculated profile and the pink line beneath the diffraction pattern represents Obs−Calc. Vertical black tick marks report the expected positions of the Bragg peaks. The inset shows the data measured at short flight times (i.e. small d-spacings).

4. Refinement

Profile refinements were done using GSAS/Expgui (Larsen & Von Dreele, 2000; Toby, 2001) starting from the coordinates reported by Farrugia (2007). Statistically significant anisotropic displacement parameters were refined for all atoms. An assumption was made that ¹H was uniformly distributed on all ²D sites, so the neutron scattering length of ²D was edited in GSAS in accordance with the concentration of ¹H determined by Raman spectroscopy; for the molybdate a value of 5.776 fm was used, and for the tungstate a value of 5.724 fm was adopted. Crystal data, data collection and structure refinement details are summarized in Table 4.

Table 4 Experimental details   Na2MoO4·2D2O Na2WO4·2D2O Crystal data Chemical formula Na2MoO4·2D2O Na2WO4·2D2O Mr 245.99 333.87 Crystal system, space group Orthorhombic, Pbca Orthorhombic, Pbca Temperature (K) 295 295 a, b, c (Å) 8.482961 (14), 10.566170 (17), 13.83195 (3) 8.482514 (15), 10.595156 (19), 13.85640 (3) V (Å3) 1239.79 (1) 1245.32 (1) Z 8 8 Radiation type Neutron Neutron μ (mm−1) 0.03 + 0.0007 * λ 0.03 + 0.0033 * λ Specimen shape, size (mm) Cylinder, 38 × 11 Cylinder, 50 × 11   Data collection Diffractometer HRPD, High resolution neutron powder HRPD, High resolution neutron powder Specimen mounting Vanadium tube Vanadium tube Data collection mode Transmission Transmission Scan method Time of flight Time of flight Absorption correction Analytical [data were corrected for self shielding using σscatt = 93.812 barns and σab(λ) = 3.657 barns at 1.798 Å during the normalization procedure. The linear absorption coefficient is wavelength dependent and is calculated as: μ = 0.0308 + 0.0007 * λ (mm−1)] analytical [data were corrected for self shielding using σscatt = 94.190 barns and σab(λ) = 19.484 barns at 1.798 Å during the normalization procedure. The linear absorption coefficient is wavelength dependent and is calculated as: μ = 0.0284 + 0.0033 * λ (mm−1)] Tmin, Tmax 0.685, 0.706 0.700, 0.603 2θ values (°) 2θfixed = 168.329 2θfixed = 168.329 Distance from source to specimen (mm) 95000 95000 Distance from specimen to detector (mm) 965 965   Refinement R factors and goodness of fit Rp = 0.013, Rwp = 0.013, Rexp = 0.007, R(F2) = 0.05255, χ2 = 3.534 Rp = 0.014, Rwp = 0.013, Rexp = 0.007, R(F2) = 0.04597, χ2 = 3.312 No. of data points 4610 4610 No. of parameters 133 133 Computer programs: HRPD control software, GSAS/Expgui (Larsen & Von Dreele, 2000: Toby, 2001), Mantid (Arnold et al., 2014: Mantid, 2013), DIAMOND (Putz & Brandenburg, 2006) and publCIF (Westrip, 2010).