1. Chemical context

The structures of binary zinc bis­(di­thio­carbamates) are always zero-dimensional (i.e. mol­ecular) (Heard, 2005) in contrast to their cadmium (Tan et al., 2016b) and mercury (Jotani et al., 2016) analogues; di­thio­carbamate is ⁻S₂CNRR'. The zinc structures can be mononuclear, distorted tetra­hedral as in Zn(S₂CNCy₂)₂ (Cox & Tiekink, 2009) or, far more commonly, binuclear as in the archetypical compound [Zn(S₂CNEt₂)₂]₂, where heavily distorted five-coordinate geometries are found for zinc as two of the ligands are chelating and the others are μ₂-tridentate (Bonamico et al., 1965; Tiekink, 2000), with the adoption of one form over the other often being related to the steric bulk of the R/R′ groups (Tiekink, 2003). However, there is no clear-cut delineation between the adoption of one structural motif over the other depending on steric bulk. This is nicely illustrated in the structure of Zn[S₂CN(i-Bu)₂]₂ which has equal numbers of both motifs (Ivanov et al., 2005). A popular process by which structures of greater dimensionality might be formed is by the addition of neutral, potentially bridging ligands. However, in the case of zinc di­thio­carbamates, complexation with bidentate ligands usually results in the isolation of zero-dimensional, binuclear mol­ecules, e.g. {Zn[S₂CN(Me)i-Pr)]₂}₂(Me₂NCH₂CH₂NMe₂) (Malik et al., 1997); [Zn(S₂CNMe₂)₂]₂(4,4′-bipyrid­yl) (Zha et al., 2010) and [Zn(S₂CNEt₂)₂]₂(Ph₂PCH₂CH₂PPh₂) (Zeng et al., 1994). Even when excess base is included in the reaction, e.g. trans-1,2-bis­(4-pyrid­yl)ethyl­ene (bpe), only the zero-dimensional binuclear compound is isolated with non-coordinating bpe solvate, i.e. Zn(S₂CNEt₂)₂]₂(bpe)·bpe (Lai & Tiekink, 2003). That this reluctance to form coordination polymers is related directly to the nature of the di­thio­carbamate ligand is seen in the adoption of zigzag chains in analogous xanthate complexes, e.g. {[Zn(S₂COR)₂]₂(bpe)}_n, for R = Et and n-Bu (Kang et al., 2010). Steric effects come into play when R = Cy whereby a binuclear species is isolated, i.e. [Zn(S₂COCy)₂]₂(bpe) (Kang et al., 2010). This difference in chemistry arises to the significant (40%) contribution of the canonical structure ^(2-)S₂CN⁽⁺⁾RR′, with two formally negatively charged sulfur atoms, which makes di­thio­carbamate a very effective chelating agent, thereby decreasing the Lewis acidity of the zinc atom.

An approach to increase the supra­molecular aggregation in the crystal structures of zinc di­thio­carbamates has been to introduce hydrogen bonding functionality into the ligands, i.e using di­thio­carbamate anions of the type ⁻S₂CN(R)CH₂CH₂OH. This influence is seen in the recent report of the structures of Zn[S₂CN(R)CH₂CH₂OH]₂(2,2′-bipyrid­yl) for R = i-Pr and CH₂CH₂OH (Safbri et al., 2016). The common feature of these structures along with those of related species with no hydrogen bonding potential, e.g. Zn(S₂CNMe₂)₂(2,2′-bipyrid­yl) (Manohar et al., 1998), is the presence of a distorted octa­hedral N₂S₄ donor set about the zinc atom. The O—H⋯O hydrogen bonding in Zn[S₂CN(R)CH₂CH₂OH]₂(2,2′-bipyrid­yl), in the case when R = CH₂CH₂OH, isolated as a 1:1 hydrate, leads to supra­molecular ladders and these extend in two dimensions via water-O—H⋯S(di­thio­carbamate) hydrogen bonds. When R = i-Pr, layers are sustained by hy­droxy-O—H⋯S hydrogen bonds (Safbri et al., 2016). As an extension of these studies, in the present report, Zn(S₂CNRR′)₂ has been complexed with 3-hy­droxy­pyridine (pyOH) to yield two 1:1 complexes. Quite different aggregation patterns are observed when R = R′ = Et (I), and R = i-Pr and R′ = CH₂CH₂OH (II). The crystal and mol­ecular structures of (I) and (II) are described herein along with an analysis of their Hirshfeld surfaces.

2. Structural commentary

Two independent mol­ecules of Zn(S₂CNEt₂)₂(pyOH) comprise the asymmetric unit of (I), Fig. 1; pyOH is 3-hy­droxy­pyridine. For the Zn1-containing mol­ecule, Fig. 1a, the Zn^II atom is chelated by two di­thio­carbamate ligands and one nitro­gen atom derived from the monodentate pyOH ligand. The S1-di­thio­carbamate ligand chelates the zinc atom forming quite different Zn—S bond lengths compared with the S3-di­thio­carbamate ligand. This is qu­anti­fied in the values of Δ(Zn—S), being the difference between the Zn—S_long and Zn—S_short bond lengths, Table 1, i.e. 0.43 and 0.15 Å, respectively. The Zn1—N3 bond length is significantly shorter than the Zn—S bonds. The NS₄ coordination geometry is highly distorted as seen in the value of τ of 0.48 (Addison et al., 1984). This value is almost exactly inter­mediate between the ideal square pyramidal geometry with τ = 0.0 and ideal trigonal pyramidal with τ = 1.0. The acute S—Zn—S chelate angles contribute to this distortion, Table 1. The widest angles in the coordination geometry are subtended by S_s—Zn—S_s (s = short) and, especially, the S_l—Zn—S_l (l = long) bond angles, Table 1. The coordination geometry for the Zn2 atom, Fig. 1b, is quite similar to that just described for the Zn1 atom. The values of Δ(Zn—S) of 0.21 and 0.25 Å are inter­mediate to those for the Zn1-mol­ecule. Even so, the differences in the Zn—S bond lengths in both mol­ecules are not that great with this observation reflected in the closeness of the C—S bond lengths, Table 1. The value of τ for the Zn2-mol­ecule is 0.53, indicating an inclination towards trigonal bipyramidal cf. the Zn1-mol­ecule.

Figure 1 The mol­ecular structures of the two independent mol­ecules comprising the asymmetric unit in (I), showing the atom-labelling scheme and displacement ellipsoids at the 70% probability level.

The mol­ecular structure of (II), Zn[S₂CN(Me)CH₂CH₂OH]₂(pyOH), is shown in Fig. 2 and selected geometric parameters are included in Table 1. The coordination modes of the di­thio­carbamate ligands in (II) are close to those observed for the Zn1-mol­ecule in (I) with Δ(Zn—S) values of 0.42 and 0.19 Å. The difference between (I) and (II) is found in the coordination geometry which is close to square pyramidal in (II), as seen in the value of τ = 0.16. In this description, the S1–S4 atoms define the basal plane with the r.m.s. deviation being 0.0501 Å. The Zn atom lies 0.7514 (4) Å above the plane in the direction of the N3 atom. The dihedral angle between the chelate rings is 63.81 (15)°, an angle significantly greater than for the comparable angles in (I), Table 1.

Figure 2 The mol­ecular structure of (II), showing the atom-labelling scheme and displacement ellipsoids at the 70% probability level.

Overlay diagrams of the three mol­ecules in (I) and (II) are shown in Fig. 3. The mol­ecules have been overlapped so that the pyOH rings are coincident. The differences in the conformations of the mol­ecules comprising (I) are clearly seen, and especially between these and the conformation in (II). Such variability in structure reflects the flexibility in the binding modes of the di­thio­carbamate ligands leading to quite distinctive coordination geometries.

Figure 3 Overlay diagrams for the Zn1- and Zn2-mol­ecules in (I) and the mol­ecule in (II) shown as red, green and blue images, respectively: (a) approximately side-on to the pyOH ring and (b) along the N—Zn bond. The mol­ecules are overlapped so that the pyOH rings are coincident.

3. Supra­molecular features

The key feature of the mol­ecular packing of (I) is the formation of hy­droxy-O—H⋯S(di­thio­carbamate) hydrogen bonds that sustain centrosymmetric, dimeric aggregates, via a 14-membered {⋯HOC₂NZnS}₂ synthon, Fig. 4a and Table 2. Additional stabilization to the dimer is provided by an intra-dimer π–π inter­action between the pyOH rings. The inter-centroid distance is 3.5484 (18) Å and the angle of inclination is 3.91 (14)° for symmetry operation 1 − x,  + y,  − z. The aggregates are further stabilized by pyOH-C—H⋯π inter­actions where the π-system is a chelate ring. Such C—H⋯π(chelate) inter­actions are increasingly being recognized as being important in the supra­molecular chemistry of metal 1,1-di­thiol­ates (Tiekink & Zukerman-Schpector, 2011; Tan et al., 2016a) and, it should be noted, routinely appear in the output from PLATON (Spek, 2009). Connections between aggregates leading to supra­molecular layers in the ab plane are also of the type C—H⋯π(chelate) but with methyl-H atoms as the donors, Fig. 4b. The connections between layers along the c direction are of the type methyl­ene-C—H⋯O(hy­droxy), Fig. 4c.

Table 2 Hydrogen-bond geometry (Å, °) for (I) Cg1 and Cg2 are the centroids of the (Zn1,S1,S2,C1) and (Zn2,S7,S8,C21) chelate rings, respectively. D—H⋯A D—H H⋯A D⋯A D—H⋯A O1—H1O⋯S8i 0.84 (2) 2.45 (1) 3.289 (2) 173 (4) O2—H2O⋯S2ii 0.84 (2) 2.31 (1) 3.143 (2) 170 (4) C8—H8A⋯Cg2 0.98 2.98 3.855 (3) 150 C13—H13⋯Cg2i 0.95 2.79 3.631 (3) 148 C20—H20C⋯Cg1iii 0.98 2.97 3.850 (3) 150 C28—H28⋯Cg1ii 0.95 2.96 3.738 (3) 140 C19—H19A⋯O2iv 0.99 2.56 3.321 (3) 134 Symmetry codes: (i) ; (ii) ; (iii) x+1, y, z; (iv) .

Figure 4 The mol­ecular packing in (I), showing (a) detail of the hy­droxy-O—H⋯S(di­thio­carbamate) hydrogen bonding, shown as orange dashed lines, leading to dimeric aggregates, (b) supra­molecular layer where the aggregates in (a) are linked by C—H⋯π(chelate) inter­actions, shown as purple dashed lines and (c) view of the unit-cell contents shown in projection down the a axis, with links between layers being of the type C—H⋯O, shown as blue dashed lines.

The addition of greater hydrogen-bonding potential in (II) results in an infinite chain, Table 3. There is an hy­droxy-O—H⋯O(hy­droxy) hydrogen bond involving the O2 and O1 atoms as the donor and acceptor, respectively. The O1-hydroxy group forms a hydrogen bond with a di­thio­carbamate-S2 atom. As shown by the `1' in Fig. 5a, these hydrogen bonds lead to a centrosymmetric 22-membered {⋯SZnSCNC<sub>2</sub>OH⋯OH}<sub>2</sub> synthon. On either side of these synthons, the pyOH hy­droxy group hydrogen bonds to the O2-hy­droxy atom and through symmetry, a centrosymmetric 24-membered {⋯OC<sub>2</sub>NCSZnNC<sub>2</sub>OH}<sub>2</sub> synthon is formed, highlighted as `2' in Fig. 5a. Alternating synthons generate a supra­molecular chain aligned along the c axis. Methyl­ene-C—H⋯π(chelate) inter­actions link mol­ecules into dimeric units, Fig. 5b. The combination of the aforementioned inter­actions lead to supra­molecular layers that stack along the b axis with no directional inter­actions between them, Fig. 5c.

Figure 5 The mol­ecular packing in (II), (a) supra­molecular chain mediated by hy­droxy-O—H⋯O(hy­droxyl), S(dithiocarbamate) hydrogen bonding, shown as orange and blue dashed lines, respectively, and non-acidic H atoms omitted, (b) detail of methyl­ene-C—H⋯π(chelate) inter­actions shown as purple dashed lines and (c) view of the unit-cell contents shown in projection down the a axis, with one layer shown in space-filling mode.

4. Hirshfeld surface analysis

The Hirshfeld surface analysis for (I) and (II) was performed as described recently (Cardoso et al., 2016). From the views of the Hirshfeld surface mapped over d_norm in the range −0.2 to + 1.3 au for the Zn1- and Zn2-containing mol­ecules of (I), Fig. 6, the presence of bright-red spots near the hy­droxy-H1O and -H2O, and di­thio­carbamate-S2 and S8 atoms represent the donors and acceptors of the O—H⋯S hydrogen bonds; these are viewed as blue and red regions on the Hirshfeld surfaces mapped over electrostatic potential (mapped over the range −0.07 to +0.10 au), Fig. 7, corresponding to positive and negative potentials, respectively. The faint-red spots appearing near the hy­droxy-O2 and methyl-C19 atoms in Fig. 6b and 6c are due to comparatively weaker inter­molecular C—H⋯O inter­actions. The intra-dimer π–π stacking inter­action between the pyOH rings, Fig. 4a, is evident through the appearance of faint-red spots near the arene-C13 and C26 atoms of the rings, Fig. 6a and 6b, forming a close inter­atomic C⋯C contact, Table 4. The diminutive-red spots near the pyOH-H13 and -H28 and di­thio­carbamate-C21 atoms, Fig. 6a–c, characterize the influence of the C—H⋯π(chelate) inter­actions; in Fig. 7, the light-blue and red regions represent the respective donors and acceptors for these inter­actions. The immediate environments around reference mol­ecules showing above inter­molecular inter­actions are illustrated in Fig. 8.

Table 4 Summary of short inter­atomic contacts (Å) in (I) and (II) Contact Distance Symmetry operation (I)     C13⋯C26 3.314 (4) 1 − x,  + y,  − z H5⋯H7B 2.36 −x, 1 − y, −z O1⋯H18B 2.61 2 − x, 1 − y, 1 − z S2⋯H20B 2.96 1 − x, 1 − y, −z S4⋯H11 2.98 1 − x, 1 − y, 1 − z S5⋯H7A 2.97 x, y, z S5⋯H14 2.94 1 − x, 1 − y, −z C1⋯H28 2.75 1 − x,  + y,  − z C21⋯H13 2.65 1 − x, − + y,  − z C29⋯H24A 2.84 1 + x, y, z (II)     S4⋯S4 3.4765 (11) 2 − x, 1 − y, 1 − z C8⋯C8 3.308 (3) 2 − x, −y, 1 − z C1⋯H6A 2.87 x, 1 + y, z C9⋯H7B 2.57 x, 1 + y, z C10⋯H10B 2.88 x, 1 + y, z H1O⋯H2O 2.37 (4) 1 − x, 1 − y, −z H2O⋯H3O 2.18 (3) 1 − x, 1 − y, 1 − z S3⋯H1O 2.91 (3) 1 − x, 1 − y, −z S3⋯H7A 2.99 1 − x, 1 − y, −z Zn⋯H2B 3.06 2 − x, 1 − y, −z O1⋯H6A 2.68 x, 1 + y, z

Figure 6 Views of the Hirshfeld surfaces for (I) mapped over dnorm for the (a) Zn1-mol­ecule and, (b) and (c) Zn2-mol­ecule.

Figure 7 Views of the Hirshfeld surfaces mapped over electrostatic potential for (I): (a) Zn1-mol­ecule and (b) Zn2-mol­ecule.

Figure 8 (a) View of the Hirshfeld surface mapped over dnorm for (I) showing O—H⋯S hydrogen bonds and short inter­atomic C⋯C and C⋯H/H⋯C contacts, indicated by black, white and red dashed lines, respectively, about the reference mol­ecule. (b) and (c) Views of Hirshfeld surface mapped with shape-index property about the Zn1 and Zn2-containing mol­ecules, respectively. The dotted blue lines labelled with 1-4 indicates C—H⋯π(chelate) inter­actions and the red dotted line shows the π–π stacking inter­action.

The presence of peripheral hy­droxy groups participating in the O—H⋯O hydrogen bonds in the structure of (II) result in the distinct bright-red spots near the respective donors and acceptor atoms on the Hirshfeld surface mapped over d_norm, Fig. 9a and 9b, and result in the blue and red regions corres­ponding to positive and negative potential on the Hirshfeld surface mapped over electrostatic potential (mapped over the range −0.12 to +0.18 au), Fig. 9c. The faint-red spots near the S4, C8, C9 and H2B atoms in Fig. 9a and 9b indicate their involvement in short inter­atomic S⋯S, C⋯C and C⋯H/H⋯C contacts, Table 4. Fig. 10a illustrates the immediate environment about a reference mol­ecule within Hirshfeld surfaces mapped over electrostatic potential and highlights the O—H⋯O hydrogen bonds. The C—H⋯π(chelate) and its reciprocal contact, i.e. π—H⋯C, and short inter­atomic S⋯S, C⋯C and C⋯H/H⋯C contacts, with labels 3–6, are shown in Fig. 10b.

Figure 9 Views of the Hirshfeld surfaces for (II) mapped over (a) and (b) dnorm and (c) electrostatic potential.

Figure 10 (a) and (b) Views of the Hirshfeld surface mapped over electrostatic potential for (II) showing O—H⋯S hydrogen bonds about the reference mol­ecule. The hydrogen bonds are indicated with black dashed lines and labelled as `1' and `2' in (a). In (b), the inter­molecular C—H⋯O (labelled with a `6' and shown as red-dashed lines) and C—H⋯π/π⋯H—C (`3', red and blue) inter­actions, and short inter­atomic S⋯S (`4', black) and C⋯H (`5', white) contacts are indicated by arrows.

The overall two-dimensional fingerprint plot for individual Zn1- and Zn2-containing mol­ecules, overall (I) and (II) are illustrated in Fig. 11a. The respective plots delineated into H⋯H, O⋯H/H⋯O, S⋯H/H⋯S, C⋯H/H⋯C, C⋯C and S⋯S contacts (McKinnon et al., 2007) are shown in Fig. 11b–g, respectively; the relative contributions from different contacts to the Hirshfeld surfaces of (I) and (II) are summarized in Table 5.

Figure 11 (a) The overall two-dimensional fingerprint plots for the Zn1-mol­ecule in (I), Zn2-mol­ecule in (I), (I) and (II), respectively, and those delineated into (b) H⋯H, (c) O⋯H/H⋯O, (d) S⋯H/H⋯S, (e) C⋯H/H⋯C, (f) C⋯C and (g) S⋯S contacts.

The fingerprint plots delineated into H⋯H contacts for (I), Fig. 11b, show different distributions of points in the individ­ual plots for Zn1- and Zn2-mol­ecules. This, as well as their different percentage contributions to the Hirshfeld surface, Table 5, confirm their distinct chemical environments. The overall plot is the superimposition of these individual plots with a pair of small peaks, at (d_e, d_i) distances shorter than their van der Waals separations, corresponding to short inter­atomic H⋯H contacts, Table 4, between the hydrogen atoms of the Zn1-mol­ecule.

The fingerprint plots delineated into O⋯H/H⋯O contacts, Fig. 11c, also exhibit slightly different profiles for the independent mol­ecules. The respective peaks at d_e + d_i ∼ 2.7 Å and ∼ 2.6 Å correspond to donors (upper region) and the acceptors (lower region) for the Zn1-mol­ecule, whereas these appear as a pair of peaks at the same d_e + d_i ∼ 2.6 Å distance for the Zn2-mol­ecule. This is likely due to the inter­acting oxygen and hydrogen atoms for the Zn1-mol­ecule being at their van der Waals separation in the donor region, i.e. at 2.72 Å, while in the acceptor region the peak corresponds to a short inter­atomic O⋯H contact, Table 4. In the plot for the Zn2-mol­ecule, this contact gives rise to the pair of peaks at d_e + d_i ∼ 2.6 Å.

The pair of spikes with their tips at different d_e + d_i distances in the fingerprint plots delineated into S⋯H/H⋯S contacts, Fig. 11d, for the Zn1- and Zn2-mol­ecules result from different hy­droxy-O—H⋯S(di­thio­carbamate) hydrogen bonds. The tips at d_e + d_i ∼ 2.4 Å in the donor region of the plot for the Zn1-mol­ecule and in the acceptor region for the Zn2-mol­ecule are due to the formation of O—H⋯S hydrogen bonds between the hy­droxy-O1 and di­thio­carbamate-S8 atoms; the other hydrogen bond, involving the O2 and S2 atoms, gives rise to tips at d_e + d_i ∼ 2.3 Å in the respective donor and acceptor regions of the plots, Fig. 11d. The plot for the overall structure results from the superimposition of individual plots and shows the symmetric distribution of points as a pair of long spikes having tips at d_e + d_i ∼ 2.3 Å. The short inter­atomic S⋯H/H⋯S contacts in the crystal of (I), Table 4, appear as a pair of aligned green points beginning at d_e + d_i ∼ 3.0 Å in the respective plots.

Almost the same percentage contribution from C⋯H/H⋯C contacts to the overall surface is made by the Zn1- and Zn2-mol­ecules, Table 5, and the respective fingerprint plots, Fig. 11e, have the same shape with tips at d_e + d_i ∼ 2.7 Å which are due to the short inter­atomic C⋯H/H⋯C contacts, Table 4, involving the atoms forming the C—H⋯π(chelate) inter­actions; the points corresponding to the other short C⋯H/H⋯C contacts are within the plot. The C⋯C contacts assigned to intra-dimer π–π stacking inter­actions between pyOH-rings have a small, i.e. 1.8%, but recognizable contribution to the Hirshfeld surface and appear as an arrow-like distribution of points around d_e = d_i = 1.8 Å in Fig. 11f. As indicated in Fig. 11g, S⋯S contacts do not figure prominently in the mol­ecular packing of (I).

The corresponding two-dimensional fingerprint plots for (II) are also given in Fig. 11. In the fingerprint plots delineated into H⋯H contacts, Fig. 11b, a pair of very thin spikes having their tips at d_e + d_i ∼ 2.3 Å indicate the presence of short inter­atomic H⋯H contacts between hy­droxy-H1O and -H2O atoms, Table 4. Also, the inter­molecular O—H⋯O hydrogen bond between the pyOH-O3 and hy­droxy-O2 atoms results in a short inter­atomic H⋯H contact between the H2O and H3O atoms, Table 4. The increase in the percentage contribution from O⋯H/H⋯O contacts to the Hirshfeld surface and the corresponding decrease in the contribution from H⋯H contacts in (II), cf. (I), Table 5, is due to the presence of dominating O—H⋯O hydrogen bonds in the crystal of (II) and is characterized as a pair of long spikes terminating at d_e + d_i ∼ 1.8 Å, Fig. 11c. The tips corresponding to the O1⋯H6A contact, Table 4, are diminished within the long spikes corresponding to dominant O—H⋯O hydrogen bonds.

The S⋯H/H⋯S contacts with the nearly same contribution to the surface of (II) as for (I), i.e. 22.2 and 22.7%, respectively, reflect the O—H⋯S hydrogen bonds and additional S⋯H contacts resulting in tips at d_e + d_i ∼ 2.9 Å in Fig. 11d and Table 4. The 12.3% contribution from C⋯H/H⋯C contacts to the surface with the tips at d_e + d_i ∼ 2.6 Å in the plot, Fig. 11e, results from the C—H⋯π(chelate) and short inter­atomic C⋯H/H⋯C contacts, Table 4. The presence of C—H⋯π(chelate) inter­actions is also indicated by the short inter­atomic Zn⋯H/H⋯Zn contacts summarized in Table 4. The presence of short inter­atomic C⋯C contacts between symmetry-related methyl-C8 atoms is identified in the respective plot, Fig. 11f, as the pair of tips at d_e + d_i ∼1.7 Å. Finally, a cone-shaped distribution of points with a 3.8% contribution to the surface from S⋯S contacts having a vertex at d_e = d_i ∼ 1.7 Å in the fingerprint plot, Fig. 11g, results from short inter­atomic contacts between S4 atoms, Table 4; the absence of analogous contacts in (I) results in a very low percentage contribution to its surface (see above).

5. Database survey

As alluded to in the Chemical context, the presence of hydroxy­ethyl groups in zinc di­thio­carbamates leads to a higher degree of recognizable supra­molecular aggregation owing to hydrogen bonding, usually of the type hy­droxy-O—H⋯O(hy­droxy) but, sometimes also of the type hy­droxy-O—H⋯S(di­thio­carbamate) (Tan et al., 2013; Jamaludin et al., 2016). The following is a brief overview of some previous structures with ethyl­hydroxy­dithio­carbamate ligands highlighting the important role of hydrogen bonding in the supra­molecular aggregation. In the what might be termed the parent binary compound, i.e. {Zn[S₂CN(CH₂CH₂OH)₂]₂}₂, the usual dimeric motif is evident but these self-assemble via strong hydrogen bonding into three-dimensional architectures in both of the polymorphs characterized thus far, with the difference between the structures being the topology of supra­molecular layers, i.e. flattened (Manohar et al., 1998) and undulating (Benson et al., 2007). When one ethyl­hydroxy group is replaced by an ethyl group, as in {Zn[S₂CN(Et)CH₂CH₂OH]₂}₂, the reduced hydrogen bonding leads to supra­molecular chains (Benson et al., 2007). Bridging ligands lead to zero-dimensional aggregates, e.g. in {Zn[S₂CN(Me)CH₂CH₂OH)₂]₂}₂L, where L is (3-pyrid­yl)CH₂N(H)C(=O)C(=O)N(H)CH₂(3-pyrid­yl). However, hydrogen bonding of the type hy­droxy-O—H⋯O(hy­droxy) links the mol­ecules into inter-woven double chains (Poplaukhin & Tiekink, 2008). The inter­esting structural chemistry is complimented by observations that some of these compounds exhibit exciting, cell-specific, anti-cancer potential (Tan et al., 2015). The foregoing suggests this is a fertile area of research, well deserving of continuing attention.

6. Synthesis and crystallization

Synthesis of (I): In a 2:1:0.5 molar ratio, Zn(S₂CNEt₂)₂, N,N′-bis­(pyridin-3-ylmeth­yl)ethane­dithiodi­amide (Zukerman-Schpector et al., 2015) and 3-hy­droxy pyridine were dissolved in chloro­form. Solvent diffusion of hexane into this solution produced pink crystals. FT–IR (cm⁻¹): ν(C=N) 1482 (s, br); ν(C—S) 987 (s). ¹H NMR (d₆-DMSO, 300 MHz): δ 9.91 (s, 1H, OH), 8.20–8.00 (m, 2H, aromatic-H), 7.30–7.10 (m, 2H, aromatic-H), 3.82 (8H, q, NCH₂, J = 7.00 Hz); 1.22 (12H, t, CH₃, J = 7.20 Hz).

Synthesis of (II): In a 1:1 molar ratio, Zn[S₂N(Me)CH₂CH₂OH]₂ and 3-hy­droxy pyridine were dissolved in a MeOH/EtOH (1:1 v/v) solution. Solvent diffusion of hexane into this solution led to the formation of colourless crystals. FT–IR (cm⁻¹): ν(C=N) 1480 (s); ν(C—S) 1002 (s). ¹H NMR (d₆-DMSO, 300 MHz): δ 9.91 (s, 1H, aromatic-OH), 8.20–8.00 (m, 2H, aromatic-H), 7.30–7.10 (m, 2H, aromatic-H), 4.91 (2H, t, OH, J = 5.50 Hz); 3.90 (4H, t, NCH₂, J = 6.25 Hz); 3.70 (4H, dt, CH₂O, J = 5.50, 5.50 Hz); 3.41 (6H, s, CH₃).

7. Refinement details

Crystal data, data collection and structure refinement details are summarized in Table 6. The carbon-bound H-atoms were placed in calculated positions (C—H = 0.95–0.99 Å) and were included in the refinement in the riding-model approximation, with U_iso(H) set to 1.2–1.5U_eq(C). The oxygen-bound H-atoms were located in difference Fourier maps but were refined with a distance restraint of O—H = 0.84±0.01 Å, and with U_iso(H) set to 1.5U_eq(O).

Table 6 Experimental details   (I) (II) Crystal data Chemical formula [Zn(C5H10NS2)2(C5H5NO)] [Zn(C4H8NOS2)2(C5H5NO)] Mr 456.99 460.94 Crystal system, space group Monoclinic, P21/c Triclinic, P Temperature (K) 98 98 a, b, c (Å) 10.032 (2), 31.955 (7), 13.233 (3) 8.8645 (19), 9.956 (2), 11.473 (3) α, β, γ (°) 90, 105.920 (2), 90 102.154 (4), 106.989 (4), 93.466 (3) V (Å3) 4079.4 (15) 938.6 (4) Z 8 2 Radiation type Mo Kα Mo Kα μ (mm−1) 1.62 1.77 Crystal size (mm) 0.50 × 0.40 × 0.15 0.37 × 0.25 × 0.25   Data collection Diffractometer Rigaku AFC12κ/SATURN724 Rigaku AFC12κ/SATURN724 Absorption correction Multi-scan (ABSCOR; Higashi, 1995) Multi-scan (ABSCOR; Higashi, 1995) Tmin, Tmax 0.687, 1.000 0.860, 1.000 No. of measured, independent and observed [I > 2σ(I)] reflections 25139, 9202, 8401 6836, 4249, 4133 Rint 0.037 0.026 (sin θ/λ)max (Å−1) 0.650 0.650   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.041, 0.106, 1.06 0.032, 0.080, 1.06 No. of reflections 9202 4249 No. of parameters 447 228 No. of restraints 2 3 Δρmax, Δρmin (e Å−3) 0.73, −0.45 0.43, −0.60 Computer programs: CrystalClear (Molecular Structure Corporation & Rigaku, 2005), SHELXS97 (Sheldrick, 2008), SHELXL2014 (Sheldrick, 2015), ORTEP-3 for Windows (Farrugia, 2012), QMol (Gans & Shalloway, 2001), DIAMOND (Brandenburg, 2006) and publCIF (Westrip, 2010).