1. Chemical context

Over recent years, polyheteronuclear complexes of 3d and 4f metals have been studied with increasing inter­est by chemists (Cristóvão et al., 2017; Cristóvão & Miroslaw, 2013; Ding et al., 2015; Tian et al., 2012; Wu & Hou, 2010). The various structures obtained (Rossi et al., 2018; Zhou et al., 2015; Ghosh & Ghosh, 2016), the physicochemical properties (Cristóvão et al., 2017) and the potential applications in fields such as luminescence (Zhao et al., 2014; Zhu et al., 2018), magneto chemistry (Chesman et al., 2012; Klokishner & Reu, 2012), electrochemistry (Yin et al., 2017) and catalysis (Lan et al., 2018) have made this chemistry very attractive. These compounds are obtained from Schiff bases, which are organic compounds having several donor sites, which are used to assemble stable structures with transition metal or lanthanide ions. Both the nature of the ligand and the nature of the metal strongly influence the properties of the compound obtained. The Schiff bases obtained by condensation between a di­amine and a well-selected keto-precursor may have two cavities of different dimensions, which can accommodate metal ions of different sizes (Andruh, 2011; Gao et al., 2012). The salen-type Schiff base obtained by the condensation of 1,2-di­amino­benzene and ortho-vanillin has two cavities of different sizes, viz. N₂O₂ and O₂O₂. The smaller inner N₂O₂ cavity consists of two imino nitro­gen atoms and two phenolato oxygen atoms and can encapsulate 3d metal ions. The larger outer O₂O₂ cavity consists of two phenolato oxygen atoms and two oxygen atoms from meth­oxy groups and can encapsulate 3d ions or lanthanide ions that have a larger ionic radius and prefer oxygen because of their hard-acid characters. By controlling the ratio of the ligand–3d metal–4f metal, it is possible to synthesize 3d–3d and 3d–4f–3d complexes. It is in this context that we used the ligand N,N′-bis­(3-meth­oxy­salicyl­idene)phenyl­ene-1,2-di­amine (H₂L) to synthesize the Zn–Zn/Zn–Sm–Zn co-crystal whose structure is described herein.

2. Structural commentary

The title compound crystallizes in the triclinic system in the space group Pī. The asymmetric unit (Fig. 1) consists a co-crystal of one trinuclear cationic unit, [SmZn₂(L)₂(SCN)₂(DMF)₂]⁺, one dinuclear anionic unit, [Zn₂(L)(SCN)₃]⁻, one uncoordinated DMF solvent mol­ecule and 0.32 of a water mol­ecule.

Figure 1 An ORTEP view of the asymmetric unit of the title compound, showing the atom-numbering scheme. Displacement ellipsoids are plotted at the 50% probability level.

In the trinuclear unit, both zinc ions are in an N₃O₂ environment, which can be characterized by the Addison parameter τ [τ = (α − β)/60; τ = 0 indicates a regular square-pyramidal geometry and τ = 1 indicates a regular trigonal bipyramid; α and β are the largest angles around the metal ions; Addison et al., 1984]. The τ values of 0.146 for Zn1 and 0.212 for Zn31 are indicative of a severely distorted square-pyramidal geometry around each zinc ion, with the apical positions of each metal ion being occupied by a terminal nitro­gen atom from an anionic thio­cyanate moiety. The apical bond lengths N121—Zn1 and N131—Zn31 are 1.9842 (17) and 1.9786 (16) Å, respectively, and are the shortest distances around these two atoms. The values are slightly lower than those found for the reported Zn₂Sm complex (Gao et al., 2012). The equatorial planes around each of these two zinc ions in the trinuclear unit are formed, respectively, by two imino nitro­gen atoms and two phenolate oxygen atoms. The diagonal basal angles, N1—Zn1—O2 = 147.54 (6)° and N2—Zn1—O3 = 138.79 (6)°, N31—Zn31—O32 = 136.30 (6)° and N32—Zn31—O33 = 149.00 (6)° significantly deviate from the ideal values of 180°. The Zn1⋯Zn31, Zn1⋯Sm1 and Sm1⋯Zn31 distances of 5.0288 (5), 3.5372 (5) and 3.5443 (5) Å, respectively, and the Zn1⋯Sm1⋯Zn31, Sm1⋯Zn31⋯Zn1 and Zn31⋯Zn1⋯Sm1 angles of 90.49 (1), 44.70 (1) and 44.81 (1)° respectively, are indicative of an isosceles triangular arrangement of the metal centres in the trinuclear unit.

In the dinuclear unit, all of the meth­oxy oxygen atoms remain uncoordinated, whereas in the trinuclear unit, for each of the two metalloligands, one of the meth­oxy atoms remains uncoordinated (O1 and O34) while the others (O4 and O31) are coordinated to the Sm^III atom. The longest bond distances around the Sm^III ion are for Sm—O4 [2.6707 (13) Å] and Sm—O31 [2.6934 (13) Å]. The Sm—O_phen­oxy distances are in the range 2.3348 (12)–2.4417 (12) Å and are comparable to those found for the Zn₂Sm complex (Gao et al., 2012) in which the mean Sm—O_phen­oxy distance is 2.332 Å. The Sm—O_DMF distances are longer than those found in a samarium complex (Kou et al., 1998) with Sm—O91 and Sm—O101 values of 2.3831 (13) and 2.3476 (13) Å, respectively (Table 1). The octa­coordinated polyhedron around the Sm^III atom is best described as slightly distorted square anti­prism. The Zn—O_phenoxo bond lengths in both the dinuclear and trinuclear units are in the range 1.9985 (13)–2.0395 (12) Å. These values are comparable with the distances for the dinuclear complex [Zn(H₂O)(valdmpn)Sm(O₂NO)₃] [where valdmpn is N,N′-bis­(3-meth­oxy­salicyl­idene)(2,2-di­methyl­propyl­idene)-1,3-di­amine); Pasatoiu et al., 2012].

In the trinuclear unit, the Zn(di-μ-phenoxo)₂Sm bridging fragments show a difference between the Zn—O and Sm—O binding lengths whose mean values are 2.0204 (su?) and 2.3860 (su?) Å, respectively. The four Zn—O_phenoxo—Sm angles have different values with an averages of 106.54 (su?) and 107.16 (su?)°, respectively, for those involving the Zn1 and Zn31 atoms. The sum of the angles in the Zn1(di-μ-phenoxo)₂Sm1 and Zn31(di-μ-phenoxo)₂Sm1 arms are 359.58 and 359.89°, respectively, indicating regular planar geometries. The dihedral angle between Zn1/O2/Sm1/O3 and Zn31/O32/Sm1/O33 plane normals is 76.01 (3)° with the displacement of the respective constituent atoms not exceeding 0.046 and 0.023 Å. In the trinuclear unit, the dihedral angles between the planes O2/Sm1/O3 and O2/Zn1/O3 and the plane normals O32/Sm1/O33 and O32/Zn1/O33 are 6.04 (6) and 3.10 (6)°, respectively. In the dinuclear unit, the dihedral angle between the O62/Zn61/O63 and O62/Zn62/O63 planes is 21.31 (10)°.

In the dinuclear unit, the Zn61 atom is tetra­coordinated while the Zn62 atom is penta­coordinated. The values of the angles around Zn61, which fall in the range 76.86 (6)–119.03 (8)°, are indicative of a distorted tetra­hedral environment. The geometry around the Zn62 atom is best described as a distorted square pyramidal, as indicated by the value of 0.105 for the Addison parameter τ. The apical position is occupied by the nitro­gen atom N141 of the thio­cyanate group with the basal plan occupied by atoms N51, N52, O62 and O63 from the ligand mol­ecule. The angles between the N141 atom in the apical position and each of the four basal plane atoms fall in the range 106.67 (6)–111.37 (7)° and are far from the ideal value of 90°. The deformation of the basal plane around the Zn62 atom is indicated by the values of the transoid [138.41 (6) and 144.96 (7)°] and cisoid angles [88.34 (6) and 88.94 (6)°], which are different from the ideal values of 180 and 90° for a square-planar geometry (Table 1). The anionic thio­cyanate ions are N donors and bind to the zinc atoms in a unidentate fashion. The Zn—N—CS bond angles in the dinuclear and trinuclear units are in the range 170.9 (5)–176.12 (18)°, indicating a quasi-linear alignment. The N—C—S angles vary between 177.7 (2) and 179.4 (2)°, showing that these three atoms adopt an almost linear alignment.

3. Supra­molecular features

Fig. 2 shows the packing arrangement in the crystal. The structure is clearly composed of alternating layers composed of cationic units and anionic units stacked along the [101] direction. The complex mol­ecules display no hydrogen-bonding contacts. The trinuclear cationic units and dinuclear anionic units are assembled into infinite layers via electrostatic inter­actions. The alternating ionic layers are held together via electrostatic inter­actions, forming a three-dimensional structure.

Figure 2 Mol­ecular representation of the title compound, showing the network of dinuclear and trinuclear complex units in layers.

4. Database survey

A survey of the Cambridge Structural Database (CSD) (Version 5.39, last update November 2017; Groom et al., 2016) shows that dinuclear complexes of the ligand bis­(2-hy­droxy-3-meth­oxy­benzyl­idene)-1,2-di­amino­benzene where the smaller N₂O₂ cage is occupied by a 3d metal and the larger, open O₂O₂ cage is occupied by one s-, p-, d- or f-block metal are well documented. Trinuclear complexes formed by two 3d metals with the above organic ligand in which the 3d metal atom is situated in the smaller N₂O₂ cage and one s-, d- or f-block metal atom is coordinated to the two larger O₂O₂ cages have also been reported: five entries corresponding to d–s [BIZBAO (Bian et al., 2008), KAZQEK (Andrez et al., 2017), KESYOY and KESZAL (Biswas et al., 2013b), LARPIG (Feng et al., 2017)], four entries correspond d–d [DEDPIM (Yang et al., 2006), OKECIS (Zhang et al., 2016), UGAMOF (Wang et al., 2008b), WOGQAL (Wang et al., 2008a)], seven correspond to s–f [FEVDUH (Wang et al., 2013), ITOVIY (Ma et al., 2016), YIMLUD, YIMMAK, YIMMEO, YIMMIS and YIMMOY (Ma et al., 2013)], twenty entries correspond to d–f [AYOKIJ (Yang et al., 2011), DEJLEK and DEJLAG (Wong et al., 2006), EBIZUM, EBOBAA and EBOBEE (Chen et al., 2011), GICBUR and GICCAY (Yang et al., 2013), KEBGUW (Pushkarev et al., 2017), MEPXEL, MEPXIP and MEPXOV (Lo et al., 2006), NOGPIJ (Bi et al., 2008a), NOMQIQ, NOMQOW and NOMQUC (Bi et al., 2008b), PALZUA (Fu et al., 2017), POXMIZ (Bi et al., 2009), VAYBEF (Liu et al., 2017), YIMMUE (Ma et al., 2013)], five entries corresponding to d–s–d [DAVZEI (Nandy et al., 2017), IZEHEB (Das et al., 2011), KESZEP, KESZIT and KESZOZ (Biswas et al., 2013a)], three entries corresponding to d–d–d [DUCJER, DUCJOB and DUCJOB01 (Wang et al., 2009)]. In all, there are thirteen entries for hetero trinuclear 3d–4f–3d complexes in which the 3d metal ion is Zn²⁺ [DEJKUZ and DEJLIO (Wong et al., 2006), DUCKAO, DUCKOC, DUCKUI, DUCLAP and DUCLET (Wang et al., 2009), EJAGIG (Liao et al., 2010), GICCEC and GICCIG (Yang et al., 2013), QUQKUK, QUQLAR and QUQLEV (Sun et al., 2016)]. Combinations of mononuclear and hetero dinuclear coordination complexes as co-crystals are observed in three cases [BICBEW and BICBIA (Biswas et al., 2013b), KAZPOT (Andrez et al., 2017)], while the combination of hetero dinuclear and hetero trinuclear coordination complexes as a co-crystal is observed in one case (Sarr et al., 2018).

5. Synthesis and crystallization

The complex [(ZnL)·(H₂O)] was prepared according to a literature method (Liu et al., 2014) with slight modification. To a solution of 1,2-di­amino­benzene (0.250 g, 2.31 mmol) in 10 mL of aceto­nitrile was added a solution of o-vanillin (0.705 g, 4.62 mmol) in 10 mL of aceto­nitrile. The resulting orange mixture was refluxed for 60 min, affording the organic H₂L ligand. After cooling, a solution of Zn(CH₃COO)₂·2H₂O (0.507 g, 2.31 mmol) in 10 mL of aceto­nitrile was added. The mixture was heated under reflux for 60 min. On cooling, the orange precipitate was filtered off, washed with 3 × 10 mL of ether and dried in air, yielding a compound formulated as [(ZnL)·(H₂O)] in 75% yield, m.p. 571–573 K. FT–IR (KBr, ν, cm⁻¹): 3307 (OH) (br, water), 1609 (C=N) 1594 (C=C), 1586 (C=C), 1488 (C=C), 1439, 1234, 1187, 731. Analysis calculated for C₂₂H₂₀ZnN₂O₅: C, 57.72; H, 4.40; N, 6.12. Found: C, 57.68; H, 4.42; N, 6.07%. Λ (S cm² mol⁻¹): 5. The filtrate of a mixture of Sm(NO₃)₃·6H₂O (0.1112 g, 0.25 mmol) and KSCN (0.1458 g, 1.5 mmol) in 20 mL of absolute ethanol was added to a DMF solution (5 mL) of [(ZnL)·(H₂O)] (0.2288 g, 0.5 mmol). The resulting solution was heated under reflux for two h. After cooling, the solution was filtered and the filtrate was kept at 298 K. After four weeks, crystals suitable for X-ray diffraction were collected and formulated as [{Zn₂(L)(SCN)₃}]·[Sm{Zn(L)(SCN)}₂(DMF)₂]·(DMF)·0.18H₂O. FT–IR (KBr, ν, cm⁻¹): 2078 (S=C=N), 1654, 1607 (C=N), 1584 (C=C), 1545 (C=C), 1463 (C=C), 1440, 1238, 1191, 731. Analysis calculated for C₈₀H_75.36Zn₄SmN₁₄O_15.18S₅: C, 46.92; H, 3.71; N, 9.57; S, 7.83%. Found: C, C, 46.87; H, 3.68; N, 9.51; S, 7.85%. Λ_M (S m² mol⁻¹): 28. μ_eff = 1.6 µB.

6. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 2. All H atoms were positioned geometrically (C—H = 0.95–0.98 Å) and refined using a riding model with U_iso(H) = 1.2U_eq(C) or 1.5U_eq(C_meth­yl, O). One of the thio­cyanate groups was found to be partially disordered such that the C and S atoms 136 of this group were distributed over two positions. In the dinuclear unit, the C and S atoms of one of the thio­cyanate groups are disordered over two sets of sites in a 0.680 (4):0.320 (4) ratio. The water mol­ecule is partially occupied [0.32 (4)].

Table 2 Experimental details Crystal data Chemical formula [Zn2(C52H50N8O10S2Sm)][(Zn2(C25H18N5O4S3)]·C3H7NO·0.32H2O Mr 2050.43 Crystal system, space group Triclinic, P Temperature (K) 100 a, b, c (Å) 14.76937 (9), 15.57623 (10), 19.28129 (13) α, β, γ (°) 94.7754 (5), 104.1999 (6), 100.9287 (5) V (Å3) 4182.75 (5) Z 2 Radiation type Mo Kα μ (mm−1) 2.02 Crystal size (mm) 0.33 × 0.21 × 0.17   Data collection Diffractometer Rigaku FRE+ equipped with VHF Varimax confocal mirrors, an AFC12 goniometer and HyPix 6000 detector Absorption correction Gaussian (CrysAlis PRO; Rigaku OD, 2018) Tmin, Tmax 0.317, 1.000 No. of measured, independent and observed [I > 2σ(I)] reflections 381624, 19170, 18483 Rint 0.031 (sin θ/λ)max (Å−1) 0.649   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.024, 0.057, 1.06 No. of reflections 19170 No. of parameters 1115 No. of restraints 14 H-atom treatment H-atom parameters constrained Δρmax, Δρmin (e Å−3) 1.48, −1.13 Computer programs: CrysAlis PRO (Rigaku OD, 2018), SHELXT (Sheldrick, 2015a), SHELXL (Sheldrick, 2015b) and OLEX2 (Dolomanov et al., 2009).