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Article

A Zn(II) Metallocycle as Platform to Assemble a 1D + 1D → 1D Polyrotaxane via π···π Stacking of an Ancillary Ligand

1
Institute of Condensed Matter Chemistry and Technologies for Energy (ICMATE), National Research Council (CNR), c/o Department of Chemical Sciences, University of Padova, via Marzolo 1, 35131 Padova, Italy
2
Department of Chemical Sciences, University of Padova, via Marzolo 1, 35131 Padova, Italy
3
Institute of Molecular Science and Technologies (ISTM), National Research Council (CNR), Via C. Golgi 19, 20133 Milano, Italy
*
Author to whom correspondence should be addressed.
Submission received: 27 September 2019 / Revised: 6 November 2019 / Accepted: 8 November 2019 / Published: 15 November 2019
(This article belongs to the Special Issue Recent Advances in Coordination Rings and Cages)

Abstract

:
A new [Zn2L2] metallocycle bearing two metal centers that can coordinate ancillary ligands and a pocket suitable to host guest molecules is reported. These two features are exploited by reacting the metallocycle with a pyridine ligand to self-assemble in the solid state an extended intertwined system with the rare 1D + 1D → 1D topology. This interpenetrated architecture is supported by π···π stacking between two pyridine units of two different metallocycles in the pocket of a third metallocycle.

Graphical Abstract

1. Introduction

MIMAs, mechanically interlocked molecular architectures, i.e., molecules that are entangled as a consequence of their topology, have attracted increasing attention [1]. They play a crucial role in natural systems, but also to exploit intriguing topologies, such as catenanes, rotaxanes, knots, and other supramolecular architectures, toward molecular machines [1]. In this context, coordination rings and cages with peculiar host-guest properties are ideal starting units to develop new intertwined architectures. Fujita et al. first reported a [2]catenane that quantitatively self-assembled starting from two Pd(II)-1,4-bis((4-pyridyl)methyl)benzene-based rings [2], and few years later, the first example of two interlocked coordination-driven cages [3]. Thereafter, the possibility to obtain catenane-like species starting from metallo-rings or -cages has been reported by several authors. In particular, pyridyl-based ligands together with square-planar metal cations (e.g., Pd(II)) are the most common building blocks for the construction of interlocked systems as recently reviewed [4]. On the other hand, the self-assembly of extended intertwined architectures, such as rotaxane oligomers [5,6,7], poly-pseudo-rotaxanes [8], or polyrotaxanes [9,10,11], is less common. Winpenny et al. have used the monoanionic [Cr7NiF8(O2CtBu)16]- ring to elegantly synthesize main-chain [n]rotaxane oligomers [5,6], a daisy chain [7] and a 1D polyrotaxane [11]. Lu et al. [8] reported the first example of a 2D poly-pseudo-rotaxane developed starting from a discrete stool-like metallocycle. Metallorings, based on transition metals capable of expanding their coordination, can be used as platforms to hierarchically assemble extended metallo-supramolecular systems [12,13,14,15] as demonstrated by Lindoy et al. This strategy has also allowed to isolate a 1D polyrotaxane, where a copper-based metallocycle and a pyridyl bridging ligand self-assemble to form a 1D coordination polymer (the axle) and a discrete rectangular box (the stopper) [10].
In order to design metallocycles bearing metal ions that can change their coordination sphere by ligand substitution or by expanding the coordination number, 2+ charged metal ions and bis-β-diketone ligands have been proven to be ideal building blocks [12,13,14,15]. For instance, we have previously demonstrated that Cu(II) and a bis-β-diketone can be used to self-assemble a constitutional dynamic library of metallocycles [16], where the interactions with σ-donor guests via Cu–N bonds drive the system toward a triangular metallobox [17,18] that can be used also to catalyze host reactions [19]. We recently described a new [Cu2L2] metallocycle, where L is the bis-β-diketone 1-(4-{[4-(3-oxo-3-phenylpropanoyl)phenyl]methyl}phenyl)-3-phenylpropane-1,3-dione. This metallocycle self-assembles in an interlocked 1D + 1D → 1D polyrotaxane when reacted with the bridging ancillary ligand 4,4′-bipyridine (bipy) [9]. In the polyrotaxane, bipy is the guest-axle and [Cu2L2] acts as the stopper as well as the hosting ring. The process is reversible since a coordinating solvent can disassemble the polyrotaxane substituting the bipy ligand. Hence, the proposed strategy to develop intertwined structures starting from metallocycles is to design and synthesize a system with two main features: (i) metal centers apt to expand their coordination sphere and (ii) host–guest properties, Figure 1a. Such key features are exploited by reacting the metallocycle with suited ligands that drive the assembly of the intertwined system by threading and coordinating the metallocycle. In our previous study [9], the formation of the 1D + 1D → 1D interpenetrated polyrotaxane was essentially driven by the bridging coordination properties of the 4,4′-bipyridine that connects two metallocycles and, at the same time, is hosted by a third metallocycle, as depicted in Figure 1b. Herein, we report a similar metallocycle based on Zn(II) and L, [Zn2L2]. Adducts with three different alcohols (MeOH, EtOH, and iPrOH) were obtained. Following the described approach, [Zn2L2] reacts with pyridine (py) and self-assembles to form an interpenetrated polyrotaxane with the rare 1D + 1D → 1D topology. Such interpenetrated architectures are supported by π···π stacking of the ancillary ligand, Figure 1c.

2. Results and Discussion

Metallocycle [Zn2L2] was synthesized in quantitative yield by combining a chloroform solution of L with a methanol (MeOH) zinc acetate solution in equimolar amount. Colorless needle-like single crystals of {[Zn2L2(MeOH)2]·2(CHCl3)}, 1, were obtained by the reactants diffusion technique of the two building blocks (zinc acetate in methanol and L in CHCl3), Figure 2a,b. The metallocycle consists of two Zn2+ ions and two ligands. The metal ions have a square pyramidal coordination geometry with a methanol molecule in the apical site. All the Zn–O distances, both for equatorial and apical sites, have similar values close to 2 Å (Table 1). The two metal ions are located at a distance of 12.5034(9) Å, while the two methylene carbon atoms of the ligands spacer have a distance of 11.472(5) Å. Compared to its copper analog [Cu2L2] [9], synthesized in the same solvents (MeOH/CHCl3), the metal ions in [Zn2L2] have a square pyramidal coordination geometry due to the coordinated methanol, while in [Cu2L2], the copper centers have a distorted planar-square coordination geometry.
By changing the synthetic conditions, we were able to isolate a similar copper-based compound {[Cu2L2(MeOH)2]·2(CH2Cl2)}, 2 (Figure 2c,d), where the Cu2+ ions have a square pyramidal coordination geometry very close to that of [Zn2L2(MeOH)2] (Table 1 for main distances). The two crystal structures are not isostructural, but the copper and zinc metallocycles have very similar dimensions and shape as evidenced by their overlapping, Figure 2g,h. A deeper analysis of the crystal packing of [Zn2L2(MeOH)2] and [Cu2L2(MeOH)2] highlighted that in both cases the coordinated methanol molecules of a metallocycle are partially hosted in the cavity of other metallocycles. These molecules interact with the hosting metallocycle through a bifurcated H-bond (Table 2) between the methanol OH group and the two oxygen atoms of the ligands facing the inside of the metallocycle cavity, Figure 3a. This leads to the formation of a supramolecular H-bond-supported 1D polymer (Figure 3b), where each metallocycle pocket hosts two methanol molecules.
Metallocycle [Zn2L2] was also prepared by employing other alcohols, such as ethanol (EtOH) and 2-propanol (iPrOH). When bulkier alcohols were used (i.e., 1-butanol and 2-butanol), we did not isolate any compound. In the case of EtOH, the structure was characterized by single crystal X-ray diffraction (SCXRD). The metallocycle {[Zn2L2(EtOH)2]·2(CHCl3)}, 3 (Figure 2e,f), crystallizes with the same unit cell of compound 1 (Table 3) and it shows the same supramolecular packing evidenced by compounds 1 and 2. The coordinated ethanol molecules of a metallocycle thread the cavity of other metallocycles, forming an H-bond (Table 2) with the hosting metallocycle. It is worthy to add that the terminal methyl group of the EtOH molecule is disordered over two different positions and this leads to two different orientations for the EtOH molecule. In the first, the molecule completely threads the cavity of a second metallocycle, while in the second one EtOH is only partially hosted by the cavity (Figure S1). In the case of the compound synthesized with isopropanol, we did not succeed in obtaining single crystals suitable for SCXRD. Only microcrystalline materials were obtained. Powder X-ray diffraction (PXRD) revealed a pattern extremely similar to those of compounds 1 and 3, Figure S2. An indexing of the PXRD pattern (Figure S3) allowed determining the unit cell leading to values similar to metallocycles 1 and 3 (Table S1). Moreover, elemental analyses confirmed the presence of two isopropanol molecules in each metallocycle according to the formula [Zn2L2(iPrOH)2]. All these evidences strongly support the conclusion that [Zn2L2(iPrOH)2] also has the previously described supramolecular packing, with the alcohol molecules of a metallocycle hosted in the cavities of other rings.
Crystal structures of the [Zn2L2(ROH)2] systems (ROH = MeOH and EtOH) confirmed that [Zn2L2] has the desired features to act as a platform for the formation of polyrotaxanes via coordination and supramolecular tools: (i) a pocket with hosting properties and (ii) the ability to coordinate other species. Moreover, the similarity between the structures of [Cu2L2(MeOH)2] and [Zn2L2(MeOH)2] strongly suggested that the Zn-based metallocycle may also be used as a platform to self-assemble polyrotaxane architectures. Hence, we reacted [Zn2L2(MeOH)2] with two similar ancillary ligands: pyridine (py) and 4,4′-bipyridine (bipy). In our previous work [9], we demonstrated that bipy coupled to the [Cu2L2] metallocycle can lead to interpenetrated polyrotaxane-like extended architectures, with bipy bridging two different metallocycles and at the same time threading a third metallocycle, Figure 1b. The reaction between [Zn2L2] and bipy led to the immediate formation of an insoluble product. Elemental analyses suggested the formation of the coordination polymer of formula [Zn2L2(bipy)]n. Despite several efforts, we were not able to isolate single crystals. An indexing of the PXRD pattern of [Zn2L2(bipy)]n led to a unit cell different from that of [Cu2L2(bipy)]n (Figures S4 and S5, Table S2). Hence, we cannot confirm the formation of an interpenetrated structure. On the contrary, the reaction between py and [Zn2L2] allowed the isolation of light yellow single crystals of {[Zn2L2(py)2]·2(CHCl3)}. Single crystals were obtained in high yield (80% ca.) from a chloroform solution of L and py layered with a methanol solution of Zn(CH3COO)2 in order to induce crystallization by the reactants diffusion technique. In [Zn2L2(py)2], 5, the zinc ions have a pyridine molecule coordinated in the apical position of a distorted square pyramid and the β-diketonate oxygen atoms in the equatorial position with distances close to 2 Å (Figure 4a,b; Table 1 for main distances) as found in the cases of [Zn2L2(MeOH)2] and [Zn2L2(EtOH)2]. When MeOH molecules were substituted with pyridine, metallocycle dimensions did not change significantly (Table 1). The analysis of the supramolecular packing showed that pyridine molecules of two different metallocycles interact via π···π stacking to form supramolecular 1D chains. Moreover, the pyridine molecule of a ring threads the cavity of another one in a manner similar to that observed for alcohol molecules. Each metallocycle hosts two pyridine molecules (Figure 4c) and these two guests are involved in π···π stacking. The interaction between the two pyridine molecules can be described as a parallel-displaced stacking (also referred to as parallel off-centered or slipped stacking), Figure 4d–e. This is the more usual conformation displayed by aromatic-nitrogen-containing ligands [20]. Moreover, it is well known that the coordination to a metal ion of the nitrogen atom further improves the stacking due to a higher polarization [20]. Figure 4e highlights the most important geometric parameters of the two interacting pyridine molecules. The distances between the pyridine planes and pyridine centroids (Cg) are in agreement with the values usually found for a coordinated pyridine [20], leading to C···C and C–H···Cg distances of 3.34 and 3.38 Å, respectively. Stacking among aromatic-nitrogen-containing ligands can strongly influence compound properties, such as luminescence [21], conductivity [22], metal uptake [23], and structural features [24], leading to interdigitated and interlocked architectures [25]. In the case of the [Zn2L2(py)2] metallocycle, stacking interactions lead to a complex supramolecular arrangement, where pairs of 1D chains entangle, with each metallocycle of one chain threaded by a py···py axle of the other chain, establishing a 1D + 1D → 1D supramolecular polyrotaxane supported by π···π stacking between ancillary ligands. This interpenetrated topology is very rare. Indeed, six examples of 1D + 1D → 1D polyrotaxane-based on metallocycle rings have been reported so far [9,26,27,28,29,30,31]. However, only for the coordination-driven [Cu2L2(bipy)]n discussed above [9] and the π···π stacking-supported polyrotaxane here presented, the extended network is based on a metallocycle [M2L2] (M = Cu2+ and Zn2+) that exists in solution as a discrete unit and that can act as a platform for the reversible self-assembly of the intertwined structure [9].

3. Materials and Methods

3.1. Synthesis

The reagents were purchased from Sigma-Aldrich (St. Louis, MO, USA) and used as received. The ligand L was prepared as previously reported [9]. The elemental analyses were carried out with a Flash 2000 Thermo Scientific analyzer (Thermo Fisher Scientific, Cambridge, UK) at the Department of Chemical Sciences of the University of Padova.

3.1.1. Synthesis of {[Zn2L2(MeOH)2]·2CHCl3} (1)

Single crystals of {[Zn2L2(MeOH)2]·2CHCl3} were obtained via reactant diffusion. A chloroform solution (15 mL) of L (46.1 mg, 0.1 mmol) was layered with a methanol solution (15 mL) of Zn(CH3COO)2·2H2O (22.0 mg, 0.1 mmol). The vial was stoppered and the solutions were allowed to diffuse slowly. After a few days, needle-shaped colorless crystals suitable for X-ray analysis were obtained. By reducing the solvent volume, more crystals were obtained. Yield 115 mg, 85%. The elemental analysis for C66H54Cl6Zn2O10, exp (%): C 59.01, H 4.15; calc (%): C 58.69, H 4.03.

3.1.2. Synthesis of {[Cu2L2(MeOH)2]·2CH2Cl2} (2)

Blade-like single crystals of {[Cu2L2(MeOH)2]·2CH2Cl2} were obtained via reactant diffusion. A CH2Cl2 solution (4 mL) of L (11.5 mg, 0.025 mmol) was layered with a methanol solution (4 mL) of Cu(CH3COO)2·H2O (5 mg, 0.025 mmol). The vial was stoppered and the solutions were allowed to diffuse slowly. After a few days, light blue single crystals suitable for X-ray analysis were obtained. Yield 12 mg, 72%. The elemental analysis for C68H56Cl4Cu2O10, exp (%): C 62.51, H 4.25; calc (%): C 62.73, H 4.33.

3.1.3. Synthesis of {[Zn2L2(EtOH)2]·2CHCl3} (3)

Single crystals of {[Zn2L2(EtOH)2]·2CHCl3} were obtained via reactant diffusion. A chloroform solution (15 mL) of L (46.0 mg, 0.1 mmol) was layered with an ethanol solution (15 mL) of Zn(CH3COO)2·2H2O (22.1 mg, 0.1 mmol). The vial was stoppered and the solutions were allowed to diffuse slowly. After a few days, colorless crystals suitable for X-ray analysis were obtained. By reducing the solvent volume, more crystals were obtained. Yield 109 mg, 79%. The elemental analysis for C68H58Cl6Zn2O10, exp (%): C 59.32, H 4.21; calc (%): C 59.24, H 4.24.

3.1.4. Synthesis of [Zn2L2(iPrOH)2] (4)

A microcrystalline powder of [Zn2L2(iPrOH)2] were obtained via reactant diffusion. A chloroform solution (15 mL) of L (46.2 mg, 0.1 mmol) was layered with an isopropanol solution (15 mL) of Zn(CH3COO)2·2H2O (22.1 mg, 0.1 mmol). The vial was stoppered and the solutions were allowed to diffuse slowly. After a few days, needle-shaped colorless crystals suitable for X-ray analysis were obtained. By reducing the solvent volume, more crystals were obtained. Yield 100 mg, 85%. The elemental analysis for C68H60Zn2O10, exp (%): C 70.05, H 5.23; calc (%): C 69.93, H 5.18.

3.1.5. Synthesis of {[Zn2L2](py)2·2CHCl3} (5)

A chloroform solution (5 mL) of ligand (55.48 mg, 0.125 mmol) and pyridine (62.5 µl, 0.75 mmol) was layered with a methanol solution (5 mL) of Zn(CH3COO)2·2H2O (28 mg, 0.125 mmol). The vial was stoppered and the solutions were allowed to diffuse slowly. After a few days, irregular-shaped colorless crystals suitable for X-ray analysis were obtained. Yield 115 mg, 80%. The elemental analysis for C74H56Cl6Zn2N2O10, exp (%): C 61.95, N 2.05, H 4.02; calc (%): C 61.52, N 1.94, H 3.91.

3.2. Crystal Structure Determination

Data were collected with an Oxford Diffraction Gemini E diffractometer (Oxford Diffraction, Oxfordshire, England), equipped with a 2K × 2K EOS CCD area detector and sealed-tube enhance (Mo) and (Cu) X-ray sources. Details of data collections, structures solution, and refinement are given as Supplementary Materials. Crystallographic Information Files (CIF) have been deposited at the Cambridge Crystallographic Data Centre as supplementary publication (CCDC 1942113–1942116, 1964015).

4. Conclusions

In conclusion, we have reported how a discrete Zn-based metallocycle can be exploited as a platform to self-assemble intertwined polyrotaxane-like architectures by using an ancillary ligand that coordinates the metallocycle. The proposed approach builds up entangled structures starting from metallocycles and projects a system with two main features (i) metal centers capable of expanding their coordination sphere and (ii) host–guest properties. The results reported here for the [Zn2L2] metallocycle, coupled with the previous studies for its [Cu2L2] analog [9], show that such metallorings are particularly suited as platforms to develop 1D + 1D → 1D polyrotaxane architectures driven either through ancillary bridging ligands (bipy) or ancillary ligands that can give π···π stacking (py).

Supplementary Materials

The following are available online at https://0-www-mdpi-com.brum.beds.ac.uk/2304-6740/7/11/137/s1, XRD details, experimental and additional structural figures; CIF and checkCIF files of the crystal structures; [Zn2L2(MeOH)2], [Zn2L2(EtOH)2], and [Zn2L2(iPrOH)2] PXRD patterns; [Zn2L2(bipy)]n synthesis and PXRD pattern.

Author Contributions

Conceptualization, M.R.; validation, M.R. and L.A.; investigation, G.T., A.C. and M.R; writing—original draft preparation, M.R.; writing—review and editing, all authors; funding acquisition, M.R. and L.A.

Funding

This research was funded by the University of Padova (grant: P-DISC #CARL-SID17 BIRD2017-UNIPD), project CHIRoN.

Conflicts of Interest

The authors declare no conflicts of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results.

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Figure 1. (a) Design of metallocycles that can expand metal ions’ coordination sphere with ancillary ligands. (b) Self-assembly of a 1D + 1D → 1D interpenetrated polyrotaxane driven by the formation of coordination bonds with a [Cu2L2] metallocycle, previous work (Reproduced with permission from [9]. 2019, Royal Society of Chemistry). (c) Self-assembly of a 1D + 1D → 1D interpenetrated polyrotaxane driven by π···π stacking with a [Zn2L2] metallocycle, present work.
Figure 1. (a) Design of metallocycles that can expand metal ions’ coordination sphere with ancillary ligands. (b) Self-assembly of a 1D + 1D → 1D interpenetrated polyrotaxane driven by the formation of coordination bonds with a [Cu2L2] metallocycle, previous work (Reproduced with permission from [9]. 2019, Royal Society of Chemistry). (c) Self-assembly of a 1D + 1D → 1D interpenetrated polyrotaxane driven by π···π stacking with a [Zn2L2] metallocycle, present work.
Inorganics 07 00137 g001
Figure 2. (a) Asymmetric unit of [Zn2L2(MeOH)2], 1. (b) Metallocycle [Zn2L2(MeOH)2], 1. (c) Asymmetric unit of [Cu2L2(MeOH)2], 2. (d) Metallocycle [Cu2L2(MeOH)2], 2. (e) Asymmetric unit of [Zn2L2(EtOH)2], 3. (f) Metallocycle [Zn2L2(EtOH)2], 3. (g,h) Top and lateral views of the overlapped metallocycles, orange 1 and green 2. Color code: Zn, dark blue; Cu, purple; O, red; C, grey; H, white. Solvent and disordered part omitted for clarity; thermal ellipsoids drawn at the 50% probability level.
Figure 2. (a) Asymmetric unit of [Zn2L2(MeOH)2], 1. (b) Metallocycle [Zn2L2(MeOH)2], 1. (c) Asymmetric unit of [Cu2L2(MeOH)2], 2. (d) Metallocycle [Cu2L2(MeOH)2], 2. (e) Asymmetric unit of [Zn2L2(EtOH)2], 3. (f) Metallocycle [Zn2L2(EtOH)2], 3. (g,h) Top and lateral views of the overlapped metallocycles, orange 1 and green 2. Color code: Zn, dark blue; Cu, purple; O, red; C, grey; H, white. Solvent and disordered part omitted for clarity; thermal ellipsoids drawn at the 50% probability level.
Inorganics 07 00137 g002
Figure 3. (a) H-bonds between two [Zn2L2(MeOH)2] metallocycles (H-bond: dotted red line). (b) H-bond-supported 1D polymer in 1. (c) H-bonds between two [Zn2L2(EtOH)2] metallocycles (H-bond: dotted red line). (d) H-bond-supported 1D polymer in 3. Color code: Zn, dark blue; O, red; C, grey; H, white.
Figure 3. (a) H-bonds between two [Zn2L2(MeOH)2] metallocycles (H-bond: dotted red line). (b) H-bond-supported 1D polymer in 1. (c) H-bonds between two [Zn2L2(EtOH)2] metallocycles (H-bond: dotted red line). (d) H-bond-supported 1D polymer in 3. Color code: Zn, dark blue; O, red; C, grey; H, white.
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Figure 4. (a,b) Asymmetric unit and metallocycle [Zn2L2(py)2], 5. (c,d) Stacking interactions between pyridine molecules of two metallocycles inside the cavity of a third metallocycle. (e) Geometric parameters of the π···π stacking. (f) The intertwined 1D supramolecular chain and a schematic representation of the self-assembly of the 1D + 1D → 1D polyrotaxane topology supported by π···π stacking between two 1D chains (turquoise and blue). Color code: Zn, dark blue; O, red; N, light blue; C, grey; H, white; centroid (Cg), bronze. Solvent omitted for clarity; thermal ellipsoids drawn at the 50% probability level.
Figure 4. (a,b) Asymmetric unit and metallocycle [Zn2L2(py)2], 5. (c,d) Stacking interactions between pyridine molecules of two metallocycles inside the cavity of a third metallocycle. (e) Geometric parameters of the π···π stacking. (f) The intertwined 1D supramolecular chain and a schematic representation of the self-assembly of the 1D + 1D → 1D polyrotaxane topology supported by π···π stacking between two 1D chains (turquoise and blue). Color code: Zn, dark blue; O, red; N, light blue; C, grey; H, white; centroid (Cg), bronze. Solvent omitted for clarity; thermal ellipsoids drawn at the 50% probability level.
Inorganics 07 00137 g004
Table 1. Main distances (Å) in the discussed metallocycles.
Table 1. Main distances (Å) in the discussed metallocycles.
Bond[Zn2L2(MeOH)2], 1 [Cu2L2(MeOH)2], 2[Zn2L2(EtOH)2], 3[Zn2L2(py)2], 5
M–O12.0153(16)1.9338(19)2.0525(16)1.9817(13)
M–O21.9951(16)1.9404(18)2.0008(17)2.0681(12)
M–O32.0304(16)1.9430(18)2.0283(17)1.9918(13)
M–O42.0023(17)1.9290(19)2.092(9)2.0948(12)
M–O5 (ROH)2.0213(19)2.245(2)2.008(3)---
M–N1 (py)---------2.0608(15)
M···M12.5034(9)12.4735(14)12.5255(7)12.8868(5)
C···C 111.472(5)11.269(6)11.481(4)11.011(3)
M = Zn1 or Cu1; 1 central methylene C atom of the ligand.
Table 2. H-bond lengths (Å) and angles (∠).
Table 2. H-bond lengths (Å) and angles (∠).
[Zn2L2(MeOH)2], 1 [Cu2L2(MeOH)2], 2[Zn2L2(EtOH)2], 3
d(O5H···O3) = 2.136(18) Åd(O5H···O3) = 2.0784(2) Åd(O5H···O1) = 1.959(12) Å
∠(O5H···O3) = 144.707(4)°∠(O5H···O3) = 164.085(3)°∠(O5H···O1) = 162.41(2)°
d(O5H···O1) = 2.281(5) Åd(O5H···O2) = 2.5744(3) Å
∠(O5H···O1) = 133.308(4)°∠(O5H···O2) = 121.359(8)°
Table 3. Crystal data and structure refinement details.
Table 3. Crystal data and structure refinement details.
Compound1235
FormulaC66H54O10Cl6Zn2 C66H56Cl4O10Cu2 C68H58O10Cl6Zn2C74H56Cl6N2O8Zn2
Formula weight1111.79 1277.98 1139.841444.64
Temperature/K143(1) 139.9(2) 150.1(2)143(1)
Crystal systemtriclinic triclinic triclinictriclinic
Space groupP-1 P-1 P-1P-1
a9.9444(5) 10.1048(9) 9.9945(3)8.8428(2)
b12.9319(6) 12.9002(11) 12.8141(3)12.4056(3)
c13.6843(7) 13.1829(12) 13.8744(4)15.8865(4)
α99.295(4) 67.018(9) 98.971(2)88.908(2)
β104.338(4) 76.573(8) 105.037(3)79.215(2)
γ111.088(5) 67.713(8) 110.495(2)74.360(2)
Volume/Å31528.45(14) 1456.7(3) 1546.47(8)1647.67(8)
Z1 1 11
Crystal size/mm3 0.41 × 0.23 × 0.13 0.3 × 0.15 × 0.02 0.35 × 0.31 × 0.250.38 × 0.22 × 0.1
Radiation MoKα (λ = 0.71073) MoKα (λ = 0.71073) MoKα (λ = 0.71073)MoKα (λ = 0.71073)
2θ range for data collection/° 4.654–58.706 4.698–52.744 4.526–58.5024.872–58.766
Reflections collected 24600 11109 1951728460
Independent reflections 7322
[Rint = 0.0330, Rsigma = 0.0349]
5954
[Rint = 0.0368, Rsigma = 0.0587]
7268
[Rint = 0.0200, Rsigma = 0.0248]
7994
[Rint = 0.0305, Rsigma = 0.0285]
Data/restraints/parameters 7322/339/384 5954/3/374 7268/18/4087994/0/415
Goodness-of-fit on F2 1.031 1.027 1.0371.029
Final R indexes
[I ≥ 2σ (I)]
R1 = 0.0465,
wR2 = 0.1176
R1 = 0.0460,
wR2 = 0.1092
R1 = 0.0483,
wR2 = 0.1308
R1 = 0.0359,
wR2 = 0.0883
Final R indexes [all data] R1 = 0.0585,
wR2 = 0.1263
R1 = 0.0610,
wR2 = 0.1202
R1 = 0.0624,
wR2 = 0.1424
R1 = 0.0428,
wR2 = 0.0931
Largest diff. peak/hole/e Å−31.80/−0.58 0.45/−0.56 1.16/−0.880.71/−0.61
CCDC1955909195590719640151955908

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Rancan, M.; Truccolo, G.; Carlotto, A.; Quici, S.; Armelao, L. A Zn(II) Metallocycle as Platform to Assemble a 1D + 1D → 1D Polyrotaxane via π···π Stacking of an Ancillary Ligand. Inorganics 2019, 7, 137. https://0-doi-org.brum.beds.ac.uk/10.3390/inorganics7110137

AMA Style

Rancan M, Truccolo G, Carlotto A, Quici S, Armelao L. A Zn(II) Metallocycle as Platform to Assemble a 1D + 1D → 1D Polyrotaxane via π···π Stacking of an Ancillary Ligand. Inorganics. 2019; 7(11):137. https://0-doi-org.brum.beds.ac.uk/10.3390/inorganics7110137

Chicago/Turabian Style

Rancan, Marzio, Giada Truccolo, Alice Carlotto, Silvio Quici, and Lidia Armelao. 2019. "A Zn(II) Metallocycle as Platform to Assemble a 1D + 1D → 1D Polyrotaxane via π···π Stacking of an Ancillary Ligand" Inorganics 7, no. 11: 137. https://0-doi-org.brum.beds.ac.uk/10.3390/inorganics7110137

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