Crystal structures of the complexes containing macrocyclic cations [M(cyclam)]2+ (M = Ni, Zn) and tetra­iodido­cadmate(2–) anion

Andriichuk, I.L.; Shova, S.; Lampeka, Y.D.

doi:10.1107/S2056989023007004

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ISSN: 2056-9890

Volume 79| Part 9| September 2023| Pages 821-826

https://doi.org/10.1107/S2056989023007004

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Crystal structures of the complexes containing macrocyclic cations [M(cyclam)]²⁺ (M = Ni, Zn) and tetraiodidocadmate(2–) anion

Irina L. Andriichuk,^a Sergiu Shova ^b and Yaroslaw D. Lampeka ^a ^*

^aL. V. Pisarzhevskii Institute of Physical Chemistry of the National Academy of Sciences of Ukraine, Prospekt Nauki 31, 03028, Kiev, Ukraine, and ^b"Petru Poni" Institute of Macromolecular Chemistry, Department of Inorganic Polymers, Aleea Grigore Ghika Voda 41A, RO-700487 Iasi, Romania
^*Correspondence e-mail: lampeka@adamant.net

Edited by J. Ellena, Universidade de Sâo Paulo, Brazil (Received 18 July 2023; accepted 7 August 2023; online 23 August 2023)

The asymmetric units of the isostructural compounds (1,4,8,11-tetraazacyclotetradecane-κ⁴N)nickel(II) tetraiodidocadmate(II), [Ni(C₁₀H₂₄N₄)][CdI₄] (I), and triiodido-1κ³I-μ-iodido-(1,4,8,11-tetraazacyclotetradecane-2κ⁴N)cadmium(II)zinc(II), [CdZnI₄(C₁₀H₂₄N₄)] (II) (C₁₀H₂₄N₄ = 1,4,8,11-tetraazacyclotetradecane, cyclam, L), consist of the centrosymmetric macrocyclic cation [M(L)]²⁺ [M = Ni^II or Zn^II] with the metal ion lying on a twofold screw axis, and the tetraiodocadmate anion [CdI₄]²⁻ located on the mirror plane. In I, the anion acts as an uncoordinated counter-ion while in II it is bound to the Zn^II atom via one of the iodide atoms, thus forming an electroneutral heterobimetallic complex [Zn(L)(CdI₄)]. The Ni^II and Zn^II ions are coordinated in a square-planar manner by the four secondary N atoms of the macrocyclic ligand L, which adopts the most energetically stable trans-III conformation. The [CdI₄]²⁻ anions in I and II are structurally very similar and represent slightly deformed tetrahedrons with average Cd—I bond lengths and I—Cd—I angles of ca 2.79 Å and 109.6°, respectively. The supramolecular organization of the complexes under consideration in the crystals is very similar and is determined by the hydrogen-bonding interactions between the secondary amino groups of the ligand L in the [M(L)]²⁺ cations and iodide atoms of the [CdI₄]²⁻ anion. In particular, the alternating cations and anions form chains running along the b-axis direction that are arranged into di-periodic sheets oriented parallel to the (101) and ( $[\overline{1}]$ 01) planes. Because both kinds of sheets are built from the same cations and anions, this feature provides the three-dimensional coherence of the crystals of I and II.

Keywords: crystal structure; nickel; zinc; cyclam; tetraiodocadmate.

CCDC references: 2281090; 2281091

1. Chemical context

Iodocadmates are one of the representatives of organic–inorganic hybrid perovskites that have been studied intensively recently. They are characterized by a number of specific electric and optical properties (Rok et al., 2021 ) that are dependent on the structure of the complex anions [Cd_mI_n]^(n−2m)− which, in turn, is determined by the structure of the organic or metallocomplex cation that is used as a structure-directing agent during the synthesis. Depending on this agent, in addition to the most common mononuclear [CdI₄]^2– anion, several types of oligonuclear {[Cd₂I₆]^2– (Park et al., 2018 ), [Cd₃I₇]⁻ (Bao et al., 2013 ), [Cd₄I₁₀]^2– (Park et al., 2014 ), [Cd₄I₁₂]^4– (Lee et al., 2016 ), [Cd₆I₁₆]^4– (Bach et al., 1997 )} and polymeric (Dobrzycki & Wózniak, 2009 ; Sharutin et al., 2012 ; Rok et al., 2021) iodocadmates have been structurally characterized. In some cases, octahedral complexes of penta- and hexadentate macrocyclic ligands have been used as the structure-directing agents in Cd^II–iodide systems (Lee et al., 2016; Park et al., 2018). At the same time, square-planar cations formed by the tetraazamacrocyclic ligand cyclam (cyclam = 1,4,8,11-tetraazacyclotetradecane, C₁₀H₂₄N₄, L), which is the most suitable for binding of 3d transition-metal ions (Yatsimirskii & Lampeka, 1985 ) were never exploited in this respect, though the fruitfulness of such an approach was shown formerly during the preparation of iodoplumbate hybrids containing the [Ni(TMC)]²⁺ cation (TMC = 1,4,8,11-tetramethyl-1,4,8,11-tetraazacyclotetradecane) (Zhang et al., 2019 ).

The present work describes the preparation and structural characterization of two representatives of iodocadmate hybrids formed under the structure-directing influence of the Ni^II and Zn^II cyclam complexes, namely (1,4,8,11-tetraazacyclotetradecane-κ⁴N)nickel(II) tetraiodidocadmate(II), [Ni(C₁₀H₂₄N₄)][CdI₄] (I), and triiodido-1κ³I-μ-iodido-(1,4,8,11-tetraazacyclotetradecane-2κ⁴N)cadmium(II)zinc(II), [CdZnI₄(C₁₀H₂₄N₄)] (II).

2. Structural commentary

The asymmetric units of the isostructural compounds I and II involve the centrosymmetric macrocyclic cation [M(L)]²⁺ [M = Ni^II and Zn^II, respectively] with the metal ions lying on a twofold screw axis and the tetraiodocadmate anion [CdI₄]²⁻. The latter acts as an uncoordinated counter-ion in I but is coordinated to the Zn^II in II, thus forming an electroneutral heterobimetallic complex [Zn(L)(CdI₄)] in which the I1 atom plays a μ₂-bridging function (Fig. 1). The Cd1, I2 and I3 atoms of the tetraiodocadmate anions in I and II are located on the mirror plane. The [CdI₄]²⁻ moieties as a whole represent slightly deformed tetrahedrons with Cd—I bond lengths and I—Cd—I angles varying in the narrow ranges not exceeding 0.08 Å and 8.2°, respectively (Table 1).

Table 1
Selected geometric parameters (Å, °)

I		II
Ni1—N1	1.940 (4)	Zn1—N1	2.157 (4)
Ni1—N2	1.943 (4)	Zn1—N2	2.169 (4)
		Zn1—N1ⁱ	2.027 (4)
		Zn1—N2ⁱ	2.053 (4)
		Zn1—I1	2.8957 (11)
Cd1—I1	2.7825 (4)	Cd1—I1	2.8208 (5)
Cd1—I2	2.8024 (7)	Cd1—I2	2.7756 (8)
Cd1—I3	2.7615 (7)	Cd1—I3	2.7442 (7)

N1—Ni1—N2ⁱ	86.35 (16)	N1—Zn1—N2ⁱ	83.73 (17)
		N1i—Zn1—N2	83.43 (17)
N1—Ni1—N2	93.65 (16)	N1—Zn1—N2	97.02 (18)
		N1i—Zn1—N2i	89.93 (16)
I1—Cd1—I1ⁱⁱ	108.39 (2)	I1—Cd1—I1ⁱⁱ	106.04 (2)
I1—Cd1—I2	106.608 (15)	I1—Cd1—I2	107.978 (16)
I1—Cd1—I3	111.407 (15)	I1—Cd1—I3	110.135 (17)
I2—Cd1—I3	112.16 (2)	I2—Cd1—I3	114.22 (3)
Symmetry codes: (i) −x + 1, −y + 1, −z + 1; (ii) x, −y + $[{3\over 2}]$ , z.

Figure 1
View of the molecular structures of I and II showing the atom-labeling scheme, with displacement ellipsoids drawn at the 30% probability level. C-bound H atoms are omitted for clarity. Hydrogen-bonding interactions are shown as dotted lines. Symmetry codes: (i) −x + 1, −y + 1, −z + 1; (ii) x, −y + $[{3\over 2}]$ , z.

The Ni^II ion in I is coordinated by the four secondary N atoms of the macrocycle L (Fig. 1a) and the centrosymmetry of the cation ensures the strict planarity of the Ni(N₄) coordination environment. The Ni—N bond lengths of ca 1.94 Å (Table 1) are typical of four-coordinated low-spin square-planar d⁸ Ni^II complexes with macrocyclic 14-membered tetraamine ligands and are much shorter than those (ca 2.05 Å) observed in the high-spin six-coordinated tetragonal–bipyramidal macrocyclic species (Yatsimirskii & Lampeka, 1985). The macrocyclic ligand L in the complex cations of I adopts the most common and energetically favorable trans-III (R,R,S,S) conformation (Bosnich et al., 1965a ; Barefield et al., 1986 ). Its five- and six-membered chelate rings are present in gauche and chair conformations with the bite angles of ca 87 and 93°, respectively (Table 1).

The bifurcating hydrogen-bonding interaction between the I1 atom of the anion and the secondary amino groups of the macrocyclic ligand of the cation as well as the N1—H1⋯I2 contact (Fig. 1a, for parameters of the hydrogen bonds see Table 2) in I arrange the [CdI₄]²⁻ fragment in such a way that its I1 atom is located just above the Ni(N₄) plane in a potential axial position of the coordination sphere of the Ni^II ion (the deviation of the mean angles N—Ni1—I1 from 90° do not exceed 4°). However, the very long distance between the metal ion and this iodide [3.3618 (3) Å] allows a coordinative interaction between them to be excluded. This is in agreement with the Ni—N bond lengths typical of the square-planar Ni^II species (see Database survey).

Table 2
Hydrogen-bond geometry (Å, °) for I

D—H⋯A	D—H	H⋯A	D⋯A	D—H⋯A
N1—H1⋯I1	0.91	3.22	3.829 (4)	127
N2—H2⋯I1	0.91	3.15	3.768 (4)	126
N1—H1⋯I2	0.91	3.03	3.742 (4)	137
N2—H2⋯I3ⁱ	0.91	3.14	3.881 (4)	140
Symmetry code: (i) $[x+{\script{1\over 2}}, y, -z+{\script{3\over 2}}]$ .

The molecular structure of II is shown in Fig. 1b. Similarly to the Ni^II atom in I, the Zn^II ion in the macrocyclic cation is coordinated by the four secondary N atoms of the macrocycle L but is displaced by 0.336 (1) Å from the N₄ plane towards the apically coordinated I1 atom. Because the [Zn(L)] unit is centrosymmetric, the metal ion was found to be disordered around a center of inversion and thus was refined with half occupancy.

The weak coordination of the iodide atom in the axial position of the macrocyclic cation (Zn1—I1 bond length ca 2.9 Å, Table 1) is reinforced by the hydrogen-bonding interaction N1—H1⋯I2 (Table 3) and results in the deformed square-pyramidal coordination environment of the Zn^II ion. Though the Zn—I—Cd angle [119.79 (4)°] and the mean Ni⋯I—Cd angle [120.13 (2)°] are practically identical, the displacement of the Zn^II ion from the mean N4 plane of the macrocycle and a shorter distance between Zn^II and the apical iodide than for Ni^II leads to the reduction of the M^II⋯Cd^II distance in II as compared to I [5.332 (1) and 4.945 (1) Å, respectively].

Table 3
Hydrogen-bond geometry (Å, °) for II

D—H⋯A	D—H	H⋯A	D⋯A	D—H⋯A
N1—H1⋯I2	0.91	2.95	3.714 (4)	142
N2—H2⋯I3ⁱ	0.91	3.11	3.871 (4)	143
Symmetry code: (i) $[x-{\script{1\over 2}}, y, -z+{\script{3\over 2}}]$ .

Similar deformed square-pyramidal coordination polyhedra (in some cases with disordering of the metal ion) have also been observed in several other five-coordinate complexes containing the [Zn(L)X] moiety (X = axial ligand) but were never found in complexes involving the [Ni(L)] fragment (see Database survey). The reasons for such differences have been considered in detail during analysis of the structure of the five-coordinate macrocyclic Zn^II complex with X = tetrathioantimonato axial ligand and were explained mainly by preferable ligand field stabilization energy for the d⁸ Ni^II electronic configuration as compared that for d¹⁰ Zn^II (Näther et al., 2022 ).

In general, the structure of the coordination polyhedron of the Zn^II ion in II has much in common with that discussed recently in detail for the [Zn(L)I]I₃ complex (Gavrish et al., 2021 ). In both compounds, the macrocyclic ligand L adopts the energetically favorable trans-III R,R,S,S) conformation (Bosnich et al., 1965a; Barefield et al., 1986), though with some peculiarities connected with the displacement of the Zn^II ion from the mean N₄ plane of the macrocycle donor atoms toward the coordinated iodide ion [0.336 (1) Å in II and 0.381 Å in triiodide complex]. In particular, the five-membered rings in II adopt gauche–envelope conformations with very similar bite angles [average value ca 83.5° (Table 1)]. The six-membered chelate rings in II are present in a chair conformation and differ from each other more significantly, both from the point of view of the Zn—N bond lengths and bite angles. So, the chelate ring in which the hydrogen atoms of the secondary amino groups have the same orientation as the displacement of the metal ion is characterized by smaller values of the Zn—N coordination bond lengths (average value 2.041 Å) and bite angle (ca 90°) as compared to the ring with the opposite orientation of the hydrogen atoms (average value 2.163 Å and ca 97°, respectively; Table 1). Similarly to [Zn(L)I]I₃, a flattening of the former six-membered chelate ring at the Zn side is observed.

It should also be mentioned that the Zn—I1 distance to the symmetry-related I1(−x + 1, −y + 1, −z + 1) atom on the other side of the N₄ plane is 3.579 (1) Å and this value seems to be too long for it to be considered as a coordination bond. This means that each component of the disordered Zn^II ion is truly five-coordinate. Therefore, the connectivity within the crystal is not uniquely defined and, in principle, the [CdI₄]²⁻ anions can interact either with one or two [Zn(L)]²⁺ cations (Fig. 2).

Figure 2
View of the two possible coordination modes of the [CdI₄]²⁻ anion in II. Symmetry code: (i) x, −y + $[{3\over 2}]$ , z.

3. Supramolecular features

The N1—H⋯I2 interactions in both I and II together with either N1—H/N2—H⋯I1 hydrogen-bonding in I or Zn—I1 coordination in II determine close similarity in the mutual spatial arrangements of the cation and anion in both compounds (Fig. 1). As expected, the supramolecular organization of the complexes under consideration is also very similar and is determined by the hydrogen-bonding interactions between the secondary amino groups of the ligand L in the [M(L)]²⁺ cations as the proton donors and I2 and I3 atoms of the [CdI₄]²⁻ anions as the proton acceptors (Tables 2 and 3). Therefore, only complex I will be used for further illustration.

As a result of the hydrogen bonds N1—H⋯I2 and N2—H⋯I3, each macrocyclic cation [M(L)]²⁺ in I and II is surrounded by four [CdI₄]²⁻ anions (Fig. 3a). In turn, each of these iodide atoms forms two bonds with different macrocyclic cations, thus resulting in binding of four cations by a single anion (Fig. 3b).

Figure 3
Nearest surrounding of the macrocyclic cation (a) and the anion (b) in I formed by N—H⋯I hydrogen bonding (black dashed lines). Symmetry codes: (i) −x + 1, −y + 1, −z + 1; (ii) x + $[{1\over 2}]$ , −y + $[{3\over 2}]$ , −z + $[{3\over 2}]$ ; (iii) −x + 1, y − $[{1\over 2}]$ , −z + 1; (iv) −x + $[{1\over 2}]$ , −y + 1, z − $[{1\over 2}]$ ; (v) x, −y + $[{3\over 2}]$ , z; (vi) −x + 1, y + $[{1\over 2}]$ , −z + 1; (vii) x − $[{1\over 2}]$ , −y + $[{3\over 2}]$ , −z + $[{3\over 2}]$ ; (viii) −x + $[{1\over 2}]$ , −y + 1, z + $[{1\over 2}]$ ; (ix) x − $[{1\over 2}]$ , y, −z + $[{3\over 2}]$ .

In the crystal, the alternating cations and anions form chains running along the b-axis direction that are arranged in two-dimensional sheets oriented parallel to the (101) and ( $[\overline{1}]$ 01) planes (Fig. 4). Since these sheets are built from the same cations and anions, this feature provides the three-dimensional coherence of crystals I and II.

Figure 4
Fragment of the two-dimensional sheet in I parallel to the (101) plane as viewed along the c axis. Iodide atoms involved in the formation of sheets parallel to the ( $[\overline{1}]$ 01) plane are shown in red. Hydrogen-bonding interactions are shown as dotted lines.

4. Database survey

A search of the Cambridge Structural Database (CSD, version 5.44; Groom et al., 2016 ) indicated that more than 20 compounds containing low-spin square-planar [Ni(L)]²⁺ cation have been characterized crystallographically. For all of them, relatively short Ni—N bond lengths in the equatorial planes typically not exceeding 1.97 Å and the absence of potential donor atoms in the axial positions of the Ni^II ion at distances shorter than 3.2 Å are inherent. Among them, several complexes containing a non-coordinated iodide anion as the counter-ion have also been described [CAFHUM (Prasad & McAuley, 1983 ); JIZTUH (Adam et al., 1991 ); JIZTUH01–JIZTUH08 (Horii et al., 2020 )]. In general, the structural parameters of these compounds, in particular, the equatorial Ni—N bond lengths (1.93–1.96 Å) and Ni⋯I distances in the axial directions (3.29–3.34 Å) are very similar to those observed in I. Interestingly, there are two complexes formed by the [Ni(L)]²⁺ cation and tetrahedral chlorometalate anions [MCl₄]²⁻ with M = Zn^II (FAGWAL; Barefield et al., 1986) and Ni^II (QASKOO; Heinemann et al., 2022 ) that also demonstrate rather weak (if any) interaction of the [Ni(L)]²⁺ cation with the halide [the Ni—Cl distances are 2.835 (average) and 3.305 Å, respectively].

In eight of the more than forty compounds containing the [Zn(L)]²⁺ cation that are present in the CSD, the Zn^II ion is five-coordinated in a square-pyramidal manner with different axial ligands including hexacyanoferrate(III) (NEPYUC; Colacio et al., 2001 ), thiolate (ICUFES and ICUFIW; Notni et al., 2006 ), thioantimonate [GALPUI (Danker et al., 2021 ) and KECVIB (Näther et al., 2022)] as well as iodide [HEGNOW (Porai-Koshits et al., 1994 ); JALBIL and JALBOR (Gavrish et al., 2021)]. In all these five-coordinate complexes, the Zn^II atom is displaced from the mean N₄ plane of the donor atoms of the macrocycle toward the axial ligand. Additionally, in some compounds (GALPUI, KECVIB and JALBOR), similar to II, some kind of disorder of the metal ion is also present. The Zn—I axial bond lengths of 2.66–2.77 Å observed in the iodide complexes are shorter than that found in II [2.8957 (11) Å].

A search of the CSD gives more than 90 hits related to the structural characterization of compounds containing the [CdI₄]²⁻ anion. Like I, the majority of them are ionic species in which the charge of the anion is compensated by organic (ca 60 hits) or metalocomplex (ca 30 hits) cations. Besides, similarly to II, in three compounds that include the complex cations formed by Cd^II [ITAFAL (Satapathi et al., 2011 ) and MATKUO (Seitz et al., 2005 )] or Cu^II (NEZXAS; Yu et al., 2007 ), the tetraiodocadmate anion displays the μ₂-bridging function with the M—I coordination bonds shorter than 3.0 Å (ca 2.83, 2.97 and 2.76 Å, respectively). In general, regardless the nature of the cation and whether the [CdI₄]²⁻ moiety is coordinated to the M^II ion, it demonstrates a slightly distorted tetrahedral shape similar to that observed in I and II.

5. Synthesis and crystallization

All chemicals and solvents used in this work were purchased from Sigma–Aldrich and were used without further purification. The complex [Ni(L)](ClO₄)₂ was prepared from ethanol solutions as described in the literature (Bosnich et al., 1965b ). The complex [Zn(L)](ClO₄)₂ was prepared analogously by mixing of equimolar amounts of L and zinc perchlorate hexahydrate in ethanol.

[Ni(L)(CdI₄)], I, was prepared as follows. [Ni(L)](ClO₄)₂ (50 mg, 0.11 mmol) was dissolved in 60 ml of an EtOH/H₂O/DMF mixture (7:3:20 by volume). CdI₂ (40 mg, 0.11 mmol) and KI (36 mg, 0.22 mmol) dissolved in 20 ml of an EtOH/H₂O mixture (1:9 by volume) were added dropwise to this solution. Brown crystals formed in several days, were filtered off, washed with ethanol and dried in air. Yield: 22 mg (23%). Single crystals of I suitable for X-ray diffraction analysis were selected from the sample resulting from the synthesis.

Alternatively, complex I can be obtained using the chloride salt of Cd^II. To 50 ml of an aqueous solution of CdCl₂ (20 mg, 0.11 mmol) were added 0.4 ml of 57% aqueous HI and this mixture was added dropwise to a solution of [Ni(L)](ClO₄)₂ (50 mg, 0.11 mmol) in 40 ml of an EtOH/H₂O mixture (3:1 by volume). Brown crystals formed in 5 days, were filtered off, washed with ethanol and dried in air. Yield: 35 mg (36%). Analysis calculated for C₁₀H₂₄CdI₄N₄Ni: C 13.66, H 2.75, N 6.37%. Found: C 13.78, H 2.60, N 6.42%.

[Zn(L)(CdI₄)], II, was prepared similarly to I. [Zn(L)](ClO₄)₂ (52 mg, 0.11 mmol) was dissolved in 32 ml of an EtOH/H₂O mixture (7:1 by volume). CdI₂ (24 mg, 0.07 mmol) and KI (20 mg, 0.13 mmol) dissolved in 12 ml of an EtOH/H₂O mixture (1:9 by volume) were added dropwise to this solution. Colorless crystals formed in several days, were filtered off, washed with ethanol and dried in air. Yield: 26 mg (46%). Analysis calculated for C₁₀H₂₄CdI₄N₄Zn: C 13.56, H 2.73, N 6.33%. Found: C 13.69, H 2.80, N 6.39%. Single crystals of II suitable for X-ray diffraction analysis were selected from the sample resulting from the synthesis.

6. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 4. H atoms in I and II were placed in geometrically idealized positions and constrained to ride on their parent atoms, with C—H distances of methylene H atoms of 0.97 Å (in I) or 0.99 Å (in II) and N—H distance of 0.91 Å with U_iso(H) values of 1.2 U_eq of the parent atoms.

Table 4
Experimental details

	I	II
Crystal data
Chemical formula	[Ni(C₁₀H₂₄N₄)][CdI₄]	[CdZnI₄(C₁₀H₂₄N₄)]
M_r	879.04	885.70
Crystal system, space group	Orthorhombic, Pnma	Orthorhombic, Pnma
Temperature (K)	200	293
a, b, c (Å)	15.4317 (3), 17.2945 (3), 7.98733 (15)	15.6013 (3), 17.2644 (3), 8.1099 (2)
V (Å³)	2131.69 (7)	2184.38 (8)
Z	4	4
Radiation type	Mo Kα	Mo Kα
μ (mm⁻¹)	7.67	7.72
Crystal size (mm)	0.1 × 0.05 × 0.03	0.15 × 0.1 × 0.1

Data collection
Diffractometer	Rigaku Xcalibur Eos	Rigaku Xcalibur Eos
Absorption correction	Multi-scan (CrysAlis PRO; Rigaku OD, 2022 $[Rigaku OD (2022). CrysAlis PRO. Rigaku Oxford Diffraction, Yarnton, England.]$ )	Multi-scan (CrysAlis PRO; Rigaku OD, 2022 $[Rigaku OD (2022). CrysAlis PRO. Rigaku Oxford Diffraction, Yarnton, England.]$ )
T_min, T_max	0.573, 1.000	0.426, 1.000
No. of measured, independent and observed [I > 2σ(I)] reflections	16993, 2644, 2204	9158, 2582, 2096
R_int	0.044	0.031
(sin θ/λ)_max (Å⁻¹)	0.667	0.666

Refinement
R[F² > 2σ(F²)], wR(F²), S	0.031, 0.064, 1.06	0.032, 0.065, 1.04
No. of reflections	2644	2582
No. of parameters	97	100
H-atom treatment	H-atom parameters constrained	H-atom parameters constrained
Δρ_max, Δρ_min (e Å⁻³)	2.57, −1.23	1.36, −0.94
Computer programs: CrysAlis PRO (Rigaku OD, 2022 $[Rigaku OD (2022). CrysAlis PRO. Rigaku Oxford Diffraction, Yarnton, England.]$ ), SHELXT (Sheldrick, 2015a ), SHELXL2018/3 (Sheldrick, 2015b ), Mercury (Macrae et al., 2020 ) and publCIF (Westrip, 2010 ).

Supporting information

CCDC references: 2281090; 2281091

Crystal structure: contains datablocks I, II. DOI: https://doi.org/10.1107/S2056989023007004/ex2074sup1.cif

Structure factors: contains datablock I. DOI: https://doi.org/10.1107/S2056989023007004/ex2074Isup2.hkl

Structure factors: contains datablock II. DOI: https://doi.org/10.1107/S2056989023007004/ex2074IIsup3.hkl

checkCIF report

Computing details top

For both structures, data collection: CrysAlis PRO (Rigaku OD, 2022); cell refinement: CrysAlis PRO (Rigaku OD, 2022); data reduction: CrysAlis PRO (Rigaku OD, 2022); program(s) used to solve structure: SHELXT (Sheldrick, 2015a); program(s) used to refine structure: SHELXL2018/3 (Sheldrick, 2015b); molecular graphics: Mercury (Macrae et al., 2020); software used to prepare material for publication: publCIF (Westrip, 2010).

(1,4,8,11-Tetraazacyclotetradecane-κ⁴N)nickel(II) tetraiodidocadmate(II) (I) top

Crystal data top

[Ni(C₁₀H₂₄N₄)][CdI₄]	D_x = 2.739 Mg m⁻³
M_r = 879.04	Mo Kα radiation, λ = 0.71073 Å
Orthorhombic, Pnma	Cell parameters from 5956 reflections
a = 15.4317 (3) Å	θ = 2.4–28.8°
b = 17.2945 (3) Å	µ = 7.67 mm⁻¹
c = 7.98733 (15) Å	T = 200 K
V = 2131.69 (7) Å³	Prism, clear dark orange
Z = 4	0.1 × 0.05 × 0.03 mm
F(000) = 1600

Data collection top

Rigaku Xcalibur Eos diffractometer	2644 independent reflections
Radiation source: fine-focus sealed X-ray tube, Enhance (Mo) X-ray Source	2204 reflections with I > 2σ(I)
Graphite monochromator	R_int = 0.044
Detector resolution: 16.1593 pixels mm^-1	θ_max = 28.3°, θ_min = 2.4°
ω scans	h = −19→19
Absorption correction: multi-scan (CrysAlisPro; Rigaku OD, 2022)	k = −23→23
T_min = 0.573, T_max = 1.000	l = −10→10
16993 measured reflections

Refinement top

Refinement on F²	Primary atom site location: dual
Least-squares matrix: full	Hydrogen site location: mixed
R[F² > 2σ(F²)] = 0.031	H-atom parameters constrained
wR(F²) = 0.064	w = 1/[σ²(F_o²) + (0.0237P)² + 2.5375P] where P = (F_o² + 2F_c²)/3
S = 1.06	(Δ/σ)_max = 0.001
2644 reflections	Δρ_max = 2.57 e Å⁻³
97 parameters	Δρ_min = −1.23 e Å⁻³
0 restraints

Special details top

Geometry. All esds (except the esd in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell esds are taken into account individually in the estimation of esds in distances, angles and torsion angles; correlations between esds in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell esds is used for estimating esds involving l.s. planes.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq
I1	0.38762 (2)	0.61952 (2)	0.75107 (4)	0.02581 (10)
I3	0.13165 (3)	0.750000	0.68459 (7)	0.03244 (13)
I2	0.34261 (3)	0.750000	0.27469 (6)	0.02831 (12)
Cd1	0.30734 (3)	0.750000	0.61887 (7)	0.02466 (13)
Ni1	0.500000	0.500000	0.500000	0.01715 (18)
N2	0.6010 (2)	0.5611 (2)	0.5599 (5)	0.0224 (8)
H2	0.577167	0.604133	0.607128	0.027*
N1	0.4693 (2)	0.5664 (2)	0.3133 (5)	0.0219 (8)
H1	0.448687	0.609197	0.366795	0.026*
C2	0.6554 (3)	0.5152 (3)	0.6750 (7)	0.0325 (12)
H2A	0.694792	0.549462	0.738857	0.039*
H2B	0.690905	0.477600	0.611403	0.039*
C1	0.4050 (3)	0.5265 (3)	0.2080 (7)	0.0335 (12)
H1A	0.434068	0.489215	0.132448	0.040*
H1B	0.372638	0.564247	0.139112	0.040*
C5	0.6550 (3)	0.5965 (3)	0.4269 (7)	0.0316 (12)
H5A	0.682907	0.555079	0.360435	0.038*
H5B	0.701410	0.627786	0.479260	0.038*
C4	0.6021 (4)	0.6473 (3)	0.3119 (7)	0.0366 (13)
H4A	0.641638	0.675793	0.236207	0.044*
H4B	0.570150	0.685815	0.379726	0.044*
C3	0.5377 (3)	0.6012 (3)	0.2072 (6)	0.0294 (11)
H3A	0.510613	0.635643	0.123246	0.035*
H3B	0.568819	0.559713	0.146499	0.035*

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
I1	0.02646 (18)	0.02180 (17)	0.0292 (2)	0.00438 (12)	0.00288 (13)	0.00314 (13)
I3	0.0221 (2)	0.0352 (3)	0.0400 (3)	0.000	0.0040 (2)	0.000
I2	0.0290 (3)	0.0274 (2)	0.0285 (3)	0.000	−0.0001 (2)	0.000
Cd1	0.0227 (3)	0.0198 (2)	0.0315 (3)	0.000	0.0013 (2)	0.000
Ni1	0.0171 (4)	0.0164 (4)	0.0179 (4)	−0.0020 (3)	−0.0014 (3)	0.0013 (3)
N2	0.018 (2)	0.021 (2)	0.029 (2)	−0.0005 (15)	0.0024 (17)	−0.0012 (17)
N1	0.026 (2)	0.0195 (19)	0.020 (2)	0.0035 (16)	−0.0001 (17)	−0.0008 (16)
C2	0.025 (3)	0.040 (3)	0.033 (3)	−0.003 (2)	−0.010 (2)	−0.003 (2)
C1	0.032 (3)	0.039 (3)	0.029 (3)	0.003 (2)	−0.010 (2)	0.003 (2)
C5	0.023 (3)	0.029 (3)	0.042 (3)	−0.011 (2)	0.001 (2)	0.000 (2)
C4	0.043 (3)	0.022 (3)	0.045 (3)	−0.006 (2)	0.012 (3)	0.004 (2)
C3	0.032 (3)	0.026 (3)	0.030 (3)	−0.001 (2)	0.008 (2)	0.007 (2)

Geometric parameters (Å, º) top

I1—Cd1	2.7825 (4)	C2—H2A	0.9900
I1—Ni1	3.3618 (3)	C2—H2B	0.9900
I3—Cd1	2.7615 (7)	C2—C1ⁱ	1.504 (7)
I2—Cd1	2.8024 (7)	C1—H1A	0.9900
Ni1—N2	1.943 (4)	C1—H1B	0.9900
Ni1—N2ⁱ	1.943 (4)	C5—H5A	0.9900
Ni1—N1ⁱ	1.940 (4)	C5—H5B	0.9900
Ni1—N1	1.940 (4)	C5—C4	1.511 (7)
N2—H2	0.9124	C4—H4A	0.9900
N2—C2	1.477 (6)	C4—H4B	0.9900
N2—C5	1.483 (6)	C4—C3	1.524 (7)
N1—H1	0.9125	C3—H3A	0.9900
N1—C1	1.472 (6)	C3—H3B	0.9900
N1—C3	1.481 (6)

Cd1—I1—Ni1	120.129 (15)	N2—C2—H2B	110.3
I1ⁱⁱ—Cd1—I1	108.39 (2)	N2—C2—C1ⁱ	106.9 (4)
I1ⁱⁱ—Cd1—I2	106.608 (15)	H2A—C2—H2B	108.6
I1—Cd1—I2	106.608 (15)	C1ⁱ—C2—H2A	110.3
I3—Cd1—I1	111.407 (15)	C1ⁱ—C2—H2B	110.3
I3—Cd1—I1ⁱⁱ	111.407 (15)	N1—C1—C2ⁱ	106.7 (4)
I3—Cd1—I2	112.16 (2)	N1—C1—H1A	110.4
N2—Ni1—I1	86.14 (11)	N1—C1—H1B	110.4
N2ⁱ—Ni1—I1	93.86 (11)	C2ⁱ—C1—H1A	110.4
N2ⁱ—Ni1—N2	180.0	C2ⁱ—C1—H1B	110.4
N1ⁱ—Ni1—I1	91.78 (11)	H1A—C1—H1B	108.6
N1—Ni1—I1	88.22 (11)	N2—C5—H5A	109.2
N1—Ni1—N2ⁱ	86.35 (16)	N2—C5—H5B	109.2
N1ⁱ—Ni1—N2ⁱ	93.65 (16)	N2—C5—C4	111.9 (4)
N1ⁱ—Ni1—N2	86.35 (16)	H5A—C5—H5B	107.9
N1—Ni1—N2	93.65 (16)	C4—C5—H5A	109.2
N1ⁱ—Ni1—N1	180.0	C4—C5—H5B	109.2
Ni1—N2—H2	102.8	C5—C4—H4A	109.1
C2—N2—Ni1	108.5 (3)	C5—C4—H4B	109.1
C2—N2—H2	114.3	C5—C4—C3	112.4 (4)
C2—N2—C5	110.4 (4)	H4A—C4—H4B	107.9
C5—N2—Ni1	119.9 (3)	C3—C4—H4A	109.1
C5—N2—H2	100.7	C3—C4—H4B	109.1
Ni1—N1—H1	101.9	N1—C3—C4	111.3 (4)
C1—N1—Ni1	109.0 (3)	N1—C3—H3A	109.4
C1—N1—H1	114.4	N1—C3—H3B	109.4
C1—N1—C3	110.1 (4)	C4—C3—H3A	109.4
C3—N1—Ni1	120.4 (3)	C4—C3—H3B	109.4
C3—N1—H1	100.7	H3A—C3—H3B	108.0
N2—C2—H2A	110.3

Ni1—N2—C2—C1ⁱ	−39.7 (5)	C2—N2—C5—C4	−177.0 (4)
Ni1—N2—C5—C4	55.7 (5)	C1—N1—C3—C4	176.4 (4)
Ni1—N1—C1—C2ⁱ	39.1 (5)	C5—N2—C2—C1ⁱ	−173.1 (4)
Ni1—N1—C3—C4	−55.5 (5)	C5—C4—C3—N1	66.9 (5)
N2—C5—C4—C3	−67.2 (6)	C3—N1—C1—C2ⁱ	173.2 (4)

Symmetry codes: (i) −x+1, −y+1, −z+1; (ii) x, −y+3/2, z.

Hydrogen-bond geometry (Å, º) top

D—H···A	D—H	H···A	D···A	D—H···A
N1—H1···I1	0.91	3.22	3.829 (4)	127
N2—H2···I1	0.91	3.15	3.768 (4)	126
N1—H1···I2	0.91	3.03	3.742 (4)	137
N2—H2···I3ⁱⁱⁱ	0.91	3.14	3.881 (4)	140

Symmetry code: (iii) x+1/2, y, −z+3/2.

Triiodido-1κ³I-µ-iodido-(1,4,8,11-tetraazacyclotetradecane-2κ⁴N)cadmium(II)zinc(II) (II) top

Crystal data top

[CdZnI₄(C₁₀H₂₄N₄)]	D_x = 2.693 Mg m⁻³
M_r = 885.70	Mo Kα radiation, λ = 0.71073 Å
Orthorhombic, Pnma	Cell parameters from 3723 reflections
a = 15.6013 (3) Å	θ = 2.4–28.5°
b = 17.2644 (3) Å	µ = 7.72 mm⁻¹
c = 8.1099 (2) Å	T = 293 K
V = 2184.38 (8) Å³	Prism, clear light colourless
Z = 4	0.15 × 0.1 × 0.1 mm
F(000) = 1608

Data collection top

Rigaku Xcalibur Eos diffractometer	2582 independent reflections
Radiation source: fine-focus sealed X-ray tube, Enhance (Mo) X-ray Source	2096 reflections with I > 2σ(I)
Graphite monochromator	R_int = 0.031
Detector resolution: 16.1593 pixels mm^-1	θ_max = 28.3°, θ_min = 2.4°
ω scans	h = −20→18
Absorption correction: multi-scan (CrysAlisPro; Rigaku OD, 2022)	k = −20→21
T_min = 0.426, T_max = 1.000	l = −10→9
9158 measured reflections

Refinement top

Refinement on F²	Primary atom site location: dual
Least-squares matrix: full	Hydrogen site location: mixed
R[F² > 2σ(F²)] = 0.032	H-atom parameters constrained
wR(F²) = 0.065	w = 1/[σ²(F_o²) + (0.0226P)² + 2.0518P] where P = (F_o² + 2F_c²)/3
S = 1.04	(Δ/σ)_max = 0.001
2582 reflections	Δρ_max = 1.36 e Å⁻³
100 parameters	Δρ_min = −0.94 e Å⁻³
0 restraints

Special details top

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq	Occ. (<1)
I1	0.60630 (2)	0.61948 (2)	0.72972 (4)	0.04273 (11)
I2	0.65629 (3)	0.750000	0.25522 (7)	0.04439 (14)
I3	0.85889 (3)	0.750000	0.67325 (8)	0.04858 (15)
Cd1	0.68815 (3)	0.750000	0.59194 (7)	0.04059 (15)
Zn1	0.50999 (12)	0.51552 (8)	0.5195 (2)	0.0325 (4)	0.5
N1	0.5302 (3)	0.5688 (2)	0.3001 (5)	0.0365 (10)
H1	0.553580	0.612411	0.344223	0.044*
N2	0.3925 (2)	0.5640 (2)	0.5681 (5)	0.0382 (10)
H2	0.413021	0.607917	0.616123	0.046*
C1	0.5928 (4)	0.5255 (3)	0.2012 (6)	0.0472 (14)
H1A	0.623595	0.560764	0.129340	0.057*
H1B	0.563348	0.487810	0.132915	0.057*
C2	0.3449 (3)	0.5153 (3)	0.6856 (8)	0.0504 (15)
H2A	0.310992	0.477403	0.626059	0.060*
H2B	0.306174	0.547248	0.750024	0.060*
C3	0.4573 (3)	0.5993 (3)	0.2050 (6)	0.0437 (13)
H3A	0.427594	0.556651	0.152125	0.052*
H3B	0.478559	0.633453	0.119263	0.052*
C4	0.3943 (4)	0.6438 (3)	0.3148 (8)	0.0552 (16)
H4A	0.426472	0.681033	0.379528	0.066*
H4B	0.355727	0.672860	0.244098	0.066*
C5	0.3405 (3)	0.5950 (3)	0.4320 (7)	0.0477 (14)
H5A	0.294530	0.626459	0.476734	0.057*
H5B	0.314889	0.552420	0.371555	0.057*

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
I1	0.0457 (2)	0.03772 (19)	0.0448 (2)	−0.01092 (14)	−0.00578 (17)	0.00554 (15)
I2	0.0440 (3)	0.0406 (3)	0.0485 (3)	0.000	0.0018 (2)	0.000
I3	0.0348 (3)	0.0515 (3)	0.0595 (4)	0.000	−0.0069 (3)	0.000
Cd1	0.0354 (3)	0.0320 (3)	0.0543 (4)	0.000	−0.0033 (3)	0.000
Zn1	0.0297 (9)	0.0377 (11)	0.0302 (9)	0.0088 (7)	0.0030 (7)	0.0069 (7)
N1	0.043 (2)	0.034 (2)	0.032 (2)	−0.0040 (18)	−0.004 (2)	0.0008 (17)
N2	0.032 (2)	0.036 (2)	0.046 (3)	0.0004 (17)	−0.002 (2)	−0.0030 (19)
C1	0.054 (3)	0.053 (3)	0.035 (3)	−0.011 (3)	0.017 (3)	−0.002 (2)
C2	0.035 (3)	0.050 (3)	0.066 (4)	0.000 (2)	0.016 (3)	−0.005 (3)
C3	0.053 (3)	0.040 (3)	0.038 (3)	−0.003 (2)	−0.010 (3)	0.010 (2)
C4	0.062 (4)	0.038 (3)	0.066 (4)	0.011 (3)	−0.027 (3)	0.007 (3)
C5	0.034 (3)	0.045 (3)	0.064 (4)	0.009 (2)	−0.005 (3)	−0.003 (3)

Geometric parameters (Å, º) top

I1—Cd1	2.8208 (5)	C1—H1A	0.9700
I1—Zn1	2.8957 (11)	C1—H1B	0.9700
I2—Cd1	2.7756 (8)	C1—C2ⁱ	1.512 (8)
I3—Cd1	2.7442 (7)	C2—H2A	0.9700
Zn1—N1	2.027 (4)	C2—H2B	0.9700
Zn1—N1ⁱ	2.157 (4)	C3—H3A	0.9700
Zn1—N2ⁱ	2.169 (4)	C3—H3B	0.9700
Zn1—N2	2.053 (4)	C3—C4	1.534 (8)
N1—H1	0.9100	C4—H4A	0.9700
N1—C1	1.468 (6)	C4—H4B	0.9700
N1—C3	1.471 (6)	C4—C5	1.522 (8)
N2—H2	0.9101	C5—H5A	0.9700
N2—C2	1.472 (6)	C5—H5B	0.9700
N2—C5	1.470 (6)

Cd1—I1—Zn1	119.79 (4)	C5—N2—Zn1ⁱ	111.8 (3)
I1—Cd1—I1ⁱⁱ	106.04 (2)	C5—N2—H2	102.3
I2—Cd1—I1	107.978 (16)	C5—N2—C2	114.5 (4)
I2—Cd1—I1ⁱⁱ	107.978 (16)	N1—C1—H1A	109.8
I3—Cd1—I1ⁱⁱ	110.135 (17)	N1—C1—H1B	109.8
I3—Cd1—I1	110.135 (17)	N1—C1—C2ⁱ	109.5 (4)
I3—Cd1—I2	114.22 (3)	H1A—C1—H1B	108.2
N1ⁱ—Zn1—I1	99.78 (12)	C2ⁱ—C1—H1A	109.8
N1—Zn1—I1	98.91 (12)	C2ⁱ—C1—H1B	109.8
N1—Zn1—N1ⁱ	161.17 (7)	N2—C2—C1ⁱ	109.5 (4)
N1—Zn1—N2ⁱ	83.73 (17)	N2—C2—H2A	109.8
N1ⁱ—Zn1—N2ⁱ	89.93 (16)	N2—C2—H2B	109.8
N1—Zn1—N2	97.02 (18)	C1ⁱ—C2—H2A	109.8
N2—Zn1—I1	95.59 (12)	C1ⁱ—C2—H2B	109.8
N2ⁱ—Zn1—I1	102.79 (12)	H2A—C2—H2B	108.2
N2—Zn1—N1ⁱ	83.43 (17)	N1—C3—H3A	109.3
N2—Zn1—N2ⁱ	161.28 (6)	N1—C3—H3B	109.3
Zn1—N1—Zn1ⁱ	18.83 (7)	N1—C3—C4	111.8 (4)
Zn1ⁱ—N1—H1	114.1	H3A—C3—H3B	107.9
Zn1—N1—H1	95.3	C4—C3—H3A	109.3
C1—N1—Zn1ⁱ	102.7 (3)	C4—C3—H3B	109.3
C1—N1—Zn1	110.6 (3)	C3—C4—H4A	108.3
C1—N1—H1	111.7	C3—C4—H4B	108.3
C1—N1—C3	114.2 (4)	H4A—C4—H4B	107.4
C3—N1—Zn1ⁱ	111.9 (3)	C5—C4—C3	116.0 (4)
C3—N1—Zn1	120.2 (3)	C5—C4—H4A	108.3
C3—N1—H1	102.7	C5—C4—H4B	108.3
Zn1—N2—Zn1ⁱ	18.72 (6)	N2—C5—C4	111.5 (4)
Zn1ⁱ—N2—H2	114.9	N2—C5—H5A	109.3
Zn1—N2—H2	96.2	N2—C5—H5B	109.3
C2—N2—Zn1ⁱ	101.8 (3)	C4—C5—H5A	109.3
C2—N2—Zn1	110.0 (3)	C4—C5—H5B	109.3
C2—N2—H2	112.1	H5A—C5—H5B	108.0
C5—N2—Zn1	119.8 (3)

Zn1—N1—C1—C2ⁱ	−30.3 (5)	Zn1—N2—C5—C4	−45.3 (5)
Zn1ⁱ—N1—C1—C2ⁱ	−48.2 (4)	N1—C3—C4—C5	−71.7 (6)
Zn1ⁱ—N1—C3—C4	63.8 (5)	C1—N1—C3—C4	180.0 (4)
Zn1—N1—C3—C4	45.0 (5)	C2—N2—C5—C4	−179.3 (4)
Zn1ⁱ—N2—C2—C1ⁱ	48.1 (5)	C3—N1—C1—C2ⁱ	−169.5 (4)
Zn1—N2—C2—C1ⁱ	30.6 (5)	C3—C4—C5—N2	71.8 (6)
Zn1ⁱ—N2—C5—C4	−64.2 (5)	C5—N2—C2—C1ⁱ	168.9 (4)

Symmetry codes: (i) −x+1, −y+1, −z+1; (ii) x, −y+3/2, z.

Hydrogen-bond geometry (Å, º) top

D—H···A	D—H	H···A	D···A	D—H···A
N1—H1···I2	0.91	2.95	3.714 (4)	142
N2—H2···I3ⁱⁱⁱ	0.91	3.11	3.871 (4)	143

Symmetry code: (iii) x−1/2, y, −z+3/2.

Selected geometric parameters (Å, °) top

I		II
Ni1—N1	1.940 (4)	Zn1—N1	2.157 (4)
Ni1—N2	1.943 (4)	Zn1—N2	2.169 (4)
		Zn1—N1ⁱ	2.027 (4)
		Zn1—N2ⁱ	2.053 (4)
		Zn1—I1	2.8957 (11)
Cd1—I1	2.7825 (4)	Cd1—I1	2.8208 (5)
Cd1—I2	2.8024 (7)	Cd1—I2	2.7756 (8)
Cd1—I3	2.7615 (7)	Cd1—I3	2.7442 (7)

N1—Ni1—N2ⁱ	86.35 (16)	N1—Zn1—N2ⁱ	83.73 (17)
		N1i—Zn1—N2	83.43 (17)
N1—Ni1—N2	93.65 (16)	N1—Zn1—N2	97.02 (18)
		N1i—Zn1—N2i	89.93 (16)
I1—Cd1—I1ⁱⁱ	108.39 (2)	I1—Cd1—I1ⁱⁱ	106.04 (2)
I1—Cd1—I2	106.608 (15)	I1—Cd1—I2	107.978 (16)
I1—Cd1—I3	111.407 (15)	I1—Cd1—I3	110.135 (17)
I2—Cd1—I3	112.16 (2)	I2—Cd1—I3	114.22 (3)

Symmetry codes: (i) -x + 1, -y + 1, -z + 1; (ii) x, -y + 3/2, z.

References

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Volume 79| Part 9| September 2023| Pages 821-826

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