2.1. Crystal syntheses

All reagents (purchased from Aldrich or Lancaster) and solvents were used as received. Crystals were obtained at room temperature (293 K) via slow evaporation in small vials sealed with perforated Parafilm^®. The very small amount of material obtained (typically few single crystals per sample) did not permit bulk analyses to be performed. However, unit-cell dimensions for single crystals from repeated syntheses were found to match those of the reported compounds.

2.2. Crystallography

X-ray data were collected on a Bruker SMART 1000 diffractometer using Mo Kα radiation. Crystal structures were solved and refined against all F² values using the SHELXTL suite of programs (Bruker AXS Inc., 1998). A summary of the data collection, and structure refinement information is provided in Table 1.¹ Data were corrected for absorption using empirical methods (SADABS) based upon symmetry-equivalent reflections combined with measurements at different azimuthal angles (Sheldrick, 1995; Blessing, 1995). Non-H atoms were refined anisotropically and H atoms associated with the halopyridinium cations were placed in calculated positions with idealized geometries. H atoms of the water molecules in the structure of (1) were located from the difference map and refined with no positional constraints. Those in structures (2a) and (2b) were modeled using the program HYDROGEN included in WinGX version 1.64.05 (Farrugia, 1999) based on combined geometric and force-field calculations on the basis of hydrogen-bonding interactions (Nardelli, 1999). In order to examine the effectiveness of this approach for calculating H-atom positions, we were able to compare the directly located positions with those calculated using the HYDROGEN program for (1). The angles between the observed and calculated H-atom positions are 15.5 and 45.7°. These are relatively large discrepancies compared with most test cases presented by Nardelli (1999). However, the qualitative picture of hydrogen bonding remains unchanged in that the water molecules provide a hydrogen-bonding link between the cations and anions.

3.1. Structure of (HPyBr-3)₂[PtCl₆]·2H₂O (1)

The structure of (1) is shown in Fig. 2 and comprises rows of [PtCl₆]^2– anions linked via hydrogen bonding to the water molecules [(Pt)Cl⋯H—O—H⋯Cl(Pt): (O)H⋯Cl 2.26, 2.39 Å; O—H⋯Cl 163.7, 158.8°]. Bridges between these hydrogen-bonded chains are then provided by the 3-bromopyridinium cations which are each linked via an N—H⋯O hydrogen bond to a water molecule [(N)H⋯O 1.68 Å; N—H⋯O 170.1°] and interact with an anion from the neighbouring row via Pt—Cl⋯Br—C halogen bonds [(Pt)Cl⋯Br(C) 3.521 Å; (Pt)Cl⋯Br 157.1°, Cl⋯Br—C 145.7°]. Anions A and B (Fig. 2) are crystallographically equivalent (asymmetric unit contains half an anion), each forming four O—H⋯Cl hydrogen bonds and two Pt—Cl⋯Br—C halogen bonds. However, anion A forms only two hydrogen bonds within the layer shown, while anion B forms two hydrogen bonds and two halogen bonds within this layer. The network is propagated in the third dimension through the formation of the two additional hydrogen bonds by anion B and two additional hydrogen bonds and two halogen bonds by anion A. Secondary C—H⋯Cl(Pt) interactions [(C)H⋯Cl(Pt) 2.68–2.74 Å, Pt—Cl⋯H 88.8–107.2°] and dipole-assisted stacking interactions of the pyridinium rings [interplanar separation 3.74 Å, inter-ring centroid–centroid distance 4.89 Å (see Hunter & Sanders, 1990; Janiak, 2000)] also contribute to the overall packing of the crystal structure.

3.2. Crystal structure of (HPyI-3)₂[PtCl₆]·2H₂O (2a)

The structure of (2a) is shown in Fig. 3 and again comprises rows of [PtCl₆]²⁻ anions linked via hydrogen bonding to the water molecules, with bridges between these hydrogen-bonded chains being provided by the 3-iodopyridinium cations through N—H⋯O hydrogen bonds to the water molecules [(N)H⋯O 1.84 Å, N—H⋯O 146.7°] and Pt—Cl⋯I—C halogen bonds involving anions from the neighbouring row [(Pt)Cl⋯I(C) 3.352 Å; (Pt)Cl⋯I 109.8°, Cl⋯I—C 176.1°]. In contrast to the structure of (1), all cation/water bridges link anions within the same layer giving a two-dimensional network. Additionally, while the linking cations shown in Fig. 2 lie parallel to the anion layer of (1) shown and are mutually stacked in pairs, the cations in (2a) are oriented perpendicular to the anion layer shown in Fig. 3. Layers within structure (2a) are more weakly linked via highly asymmetric bifurcation of the N—H⋯O hydrogen bond to involve water molecules in a neighbouring layer [minor component: (N)H⋯O 2.49 Å; N—H⋯O 119.1°] and through the dipole-assisted stacking of cations (see Hunter & Sanders, 1990; Janiak, 2000) associated with neighbouring layers (interplanar separations 3.47, 3.35 Å; inter-ring centroid–centroid distances 4.52, 3.86 Å, respectively). The calculated water H-atom positions suggest that the bridge formed between anions within a row is of the form (Pt)Cl⋯H—O—H⋯Cl₃(Pt), i.e. involving interactions as shown in Figs. 2(a) and (c). Minor errors in the positions of the H atoms could potentially lead to some quantitative reinterpretation of specific O—H⋯Cl interactions, although the qualitative description, namely that water molecules interact with one cation and two anions via hydrogen bonds, would remain unchanged. Several C—H⋯Cl(Pt) interactions [(C)H⋯Cl(Pt) 2.59–2.84 Å with typical Pt—Cl⋯H interaction geometry far from linear (Brammer et al., 2001; Thallapally & Nangia, 2001)] also contribute to the overall packing of the crystal structure.

3.3. Crystal structure of (HPyI-3)₂[PtCl₆]·2H₂O (2b)

The structure of (2b) is shown in Fig. 4 and shows many similarities but some key differences from the polymorphic form (2a). Notably, the symmetry is lower for (2b) [space group P for (2b) versus P2/n for (2a)] permitting the two independent cations and water molecules to adopt different interaction geometries. Similarly to that observed in (2a), rows of [PtCl₆]²⁻ anions are linked via hydrogen bonding to the water molecules, with bridges between these hydrogen-bonded chains being provided by the 3-iodopyridinium cations through N—H⋯O hydrogen bonds to the water molecules [(N)H⋯O 1.72, 1.98 Å; N—H⋯O 161.3, 138.8°] and Pt—Cl⋯I—C halogen bonds involving anions from the neighbouring row [(Pt)Cl⋯I(C) 3.364, 3.422 Å; (Pt)Cl⋯I 116.8, 104.1°, Cl⋯I—C 170.9, 173.1°]. Again, as seen in (2a), all cation/water bridges link anions within the same layer giving a two-dimensional network and the cations are oriented perpendicular to the anion layer shown in Fig. 4(a). Layers within structure (2b) are again linked via bifurcation of the N—H⋯O hydrogen bonds to involve water molecules in a neighbouring layer. However, this arises in only one of the two independent cation/water pairings (A in Fig. 4b) and is a more symmetric bifurcation [minor component: (N)H⋯O 2.26 Å; N—H⋯O 127.7°; see (III), Fig. 5] than observed in (2a). The second cation/water pairing (B in Fig. 4b) plays an analogous structural role, but the water molecules are markedly further apart and the N—H⋯O hydrogen bonds can no longer be described as bifurcated [see (IV), Fig. 5]. Dipole-assisted stacking of cations associated with neighbouring layers also clearly contributes to the organization of the layers [interplanar separations 4.60, 3.91 Å, inter-ring centroid–centroid distances 3.59, 3.38 Å, respectively].

The calculated water H-atom positions suggest that the bridge formed between anions within a row is of the form (Pt)Cl⋯H—O—H⋯Cl₂(Pt) for one water molecule and (Pt)Cl⋯H—O—H⋯Cl(Pt) for the other. Several C—H⋯Cl(Pt) interactions [(C)H⋯Cl(Pt) 2.61–2.86 Å with typical Pt—Cl⋯H interaction geometry far from linear (Brammer et al., 2001; Thallapally & Nangia, 2001)] also contribute to the overall packing of the crystal structure.

4.1. The water molecules

Based upon previous studies (Brammer et al., 2003; Willett et al., 2003) it is anticipated that the anhydrous compounds (HPyBr-3)₂[PtCl₆] and (HPyI-3)₂[PtCl₆] would form crystals in which anions and cations were arranged in networks and linked via N—H⋯Cl_nPt (n = 1–3) hydrogen bonds and Pt—Cl⋯X′—C halogen bonds (X′ = Br, I). In this study the opportunity has arisen to examine the effect of inclusion of water molecules upon the anticipated interactions. By consideration of hydrogen bonds and halogen bonds in terms of Lewis acid–Lewis base interactions, one might anticipate that the water molecules should be capable in principle of expanding either the hydrogen bonding or halogen-bonding interaction via insertion, as shown in Fig. 6. Insertion of water molecules into hydrogen-bonded networks is well established, a common example being the expansion of the well known carboxylic acid hydrogen-bonded dimer through such insertion. Insertion into the halogen bond must also be considered since the two new interactions that would be formed are well established, namely O—H⋯Cl(M) (Brammer et al., 2001) and O⋯Br—C or O⋯I—C (Lommerse et al., 1996) interactions.

Crystals of both compounds have been obtained as dihydrates, with two polymorphic forms of (HPyI-3)₂[PtCl₆]·2H₂O [(2a) and (2b)] being obtained under different conditions. These structures enable some insight into the role of the water molecule in these structures and in particular the interplay of the water molecule hydrogen-bond donor and acceptor functions with those of Lewis acidic functional groups of the cation (N—H and C—X′, X′ = Br, I) and the Lewis basic groups of the anion, i.e. the chloride ligands. In all three structures N—H⋯Cl(Pt) hydrogen bonding is not observed and furthermore the water molecules are inserted exclusively into this putative hydrogen bond, as illustrated schematically in Fig. 6(a). However, the formation of the anticipated Pt—Cl⋯X′—C halogen bonds (X′ = Br, I) appears to be unaffected. In a related study of a hydrogen-bonded tetrachloroplatinate(II) compound, Angeloni & Orpen (2001) have observed the insertion of water molecules into the O—H⋯O hydrogen bonds of a carboxylic acid dimer rather than into N—H⋯Cl(Pt) hydrogen bonds linking cations and anions.

Simple inorganic hydrates have been comprehensively described and classified (Wells, 1984), and the Cambridge Structural Database (CSD; Allen, 2002) has been used to establish typical hydrogen-bonding motifs of water molecules in small biological molecules (Jeffrey & Maluszynska, 1990). A very recent study has also examined hydrogen-bonding patterns in hydrates of molecular organic compounds (Gillon et al., 2003) and reflects great current interest in hydrates and solvates of pharmaceutical compounds. In the latter study three distinct hydrogen-bonding roles for water molecules have been found in molecular organic crystals:

(i) water is exclusively a donor or an acceptor forming only one hydrogen bond, (ii) water is exclusively a donor or an acceptor forming two hydrogen bonds and (iii) water is both a donor and an acceptor with two, three or four interactions with neighbouring molecules.

In the three structures described herein, the role of the water molecules falls into the last of these categories. In all cases the water molecules serve as hydrogen-bond donors to two separate [PtCl₆]²⁻ anions, linking the anions in rows. Each water molecule also serves as a hydrogen-bond acceptor with either one or two cations as summarized in Fig. 5.

4.2. Halogen bonds

Halogen bonds (Pt—Cl⋯X′—C, X′ = Br, I) are formed in all three structures and provide a linkage between the cations and anions which is consistent with previous findings in the anhydrous salts of halopyridinium tetrachloro- and tetrabromometallates (Brammer et al., 2003; Willett et al., 2003) and related to those observed for halopyridinium halides (Freytag et al., 1999). The geometries of the halogen bonds are summarized in Table 2.

The two polymorphs of (HPyI-3)₂[PtCl₆]·2H₂O [(2a) and (2b)] exhibit Pt—Cl⋯I–C halogen bonds that are 8–10% shorter than a simple van der Waals separation, but not as short as analogous Co—Cl⋯I—C halogen bonds reported for (HPyI-3)₂[CoCl₄] (d_ClX = 3.213, 3.430 Å, R_ClX = 0.868, 0.920; Brammer et al., 2003), where a greater partial negative charge associated with the chloride ligands might be expected to enhance the interaction. The Pt—Cl⋯I—C geometries are consistent with the Lewis acidic behaviour by the C—I group of the cation (approximately linear C—I⋯Cl) and Lewis basic behaviour of the chloride ligands of the anion (highly bent Pt—Cl⋯I angle). The bromopyridinium analogue (1), however, exhibits a Pt—Cl⋯Br—C halogen bond that is only 2% shorter than the van der Waals separation, suggesting a weaker interaction. The C—Br⋯Cl and Pt—Cl⋯Br angles lie between the Lewis acid and base geometric extremes found in (2a) and (2b), and are most likely distorted from the energetically optimum geometry for the Pt—Cl⋯Br—C interaction to accommodate other interactions within the crystal. Such geometric distortions are common in weaker intermolecular interactions as has been well studied in comparisons of weak hydrogen bonds involving C—H donors with stronger ones involving N—H or O—H donors (Steiner, 2002; Desiraju & Steiner, 1999).

Thus, the halogen bonds present structures uninterrupted by the presence of the water molecules. This is a valuable indication of the robustness of the M—Cl⋯X′—C interaction in the presence of competing interactions and lends support to the potential utility of such interactions as synthons in inorganic crystal engineering. Related, but more extensive competition reactions have been conducted by Metrangolo, Resnati and coworkers using strongly electron-accepting perfluorodiiodobenzene and perfluorodiiodoalkanes to establish the dominance of N⋯I—C and O⋯I—C halogen bonds over potentially competing O—H⋯N and O—H⋯O hydrogen bonds in organic co-crystal formation (Corradi et al., 2000).

Finally, it is interesting to note that there is also a close contact between chloride ligands of neighbouring anions in structures (2a) [(Pt)Cl⋯Cl(Pt) 3.370 Å; Pt—Cl⋯Cl 165.7°] and (2b) [(Pt)Cl⋯Cl(Pt) 3.366 Å; Pt—Cl⋯Cl 158.0°]. However, it is not anticipated to be attractive in nature due to the negative charge associated with the anions. The closest (Pt)Cl⋯Cl(Pt) contact in (1) is 3.752 Å.