Back
 JCPT  Vol.10 No.1 , January 2021
Coordination Polymer of Cobalt (ΙΙ) Nitrate with Imidazole: Synthesis, Properties and Crystal Structure
Abstract: Layered metal-organic polymer [Co(L)6](NO3)2 was obtained (where, L = C3H4N2) and structurally characterized by X-Ray diffraction (XRD) analysis. Crystals have trigonal structure: a = b = 12.3555(10) Ǻ, c = 14.4833(3) Ǻ; α = β = 90˚; γ = 120˚; V = 1914.78(5) Ǻ; R3, Z = 3. The structure of the complex consists of discrete [Co(L)6]2+ cations and anions. The Co2+ ion has a centrosymmetric octahedron configuration with a coordination site—CoN6. The ligand is coordinated monodentate through the pyridine nitrogen atom (N3) to the Co2+ ion with an average Co-N bond distance of 2.1590 Ǻ. Molecules in the coordination polymer are additionally linked by intermolecular hydrogen bonds through the pyrrole nitrogen atom (-N-H) and oxygen of the nitrate group with the formation of a polymer chain of the type: N-H…O. The chains are linked in layers along the (001) plane.

1. Introduction

Metal-organic coordination polymers of the compound of 3d-metals with multidentate ligands can be considered as precursors for the creation of organic hybrid materials. The increased attention to such compounds is associated with their unusual structures and the possibility of obtaining multifunctional materials on their basis. The latter should include magnetoactive [1], luminescent [2], sorption [3] and bioactive [4] properties.

The preparation of coordination polymers of various types (linear, chain, layered, framework) [5] depends on many factors, such as the coordination preference of metals, geometric characteristics of organic ligands, the nature of counterions, etc. Among the ligands suitable for the synthesis of compounds with the above-mentioned properties, such a ligand likes an imidazole containing two different nitrogen atoms: pyridine and pyrrole. Consequently, imidazole can act as both a chelating and a bridging ligand [6]. In addition, imidazole can participate in the formation of hydrogen bonds through the -N-H groups of imidazole with the counter ion ( NO 3 ), creating supramolecular assemblies.

This work presents the results of synthesis, IRS, DTG, X-ray structural analysis of the layered metal-organic polymer [Co(L)6](NO3)2 (I).

2. Experimental

We used the reagents Co(NO3)2·6H2O (reagent grade) imidazole (Sigma Aldrich, 99.5%). The complex was obtained by the interaction of cobalt nitrate with imidazole according to the well-known method [7]. The compound is crystals of light lilac color, stable in air, Tm. = 238˚С.

Elemental analysis of the complex:

Found%: C = 35.05; H = 3.89; N = 32.08; Co = 9.11.

Calculated%: C = 36.52; H = 4.05; N = 33.14; Co = 9.96.

Elemental analysis was performed on an EA-3000 elemental analyser (Euro-Vector). IR spectra of the ligand and the synthesized complex (I) were recorded in tablets on a Nicolette Avatar spectrophotometer in the range of 400 - 4000 cm−1. The thermogram of the compound was recorded on a Paulik-Paulik-Erdey system derivatograph in an air atmosphere when heated from 20˚C to 1000˚C at a heating rate of 10 degree per minute. Alumina (Al2O3) served as the standard. X-ray structural analysis of the crystal was carried out at a temperature of 100 K on a Bruker Quest D8 diffractometer equipped with a Photon-ΙΙΙ detector and a water-cooled X-ray tube (30 mA, 50 kB, λ (MoKα) = 0.71073 Ǻ, graphite monochromator, φ- and ω-scanning , step 0.35˚, exposure time 2 sec). Registration of reflections and establishment of the structure was carried out in the APEX software [8] package ΙΙΙ. The reflection intensities were integrated using the SAINT program [9]. The reflection intensities were corrected to take into account the absorption of radiation by the crystal using the SADABS program [10] semi-empirically using equivalent reflections. The space group is determined using statistics of systematically absent reflections. The structure was solved by a direct method using SHELXT [11]. The positions of all atoms were found from the difference electron density map. The structure was refined by the least squares method in the anisotropic (for hydrogen atoms—isotropic) full matrix approximation in F2 in the SHELXL-2018 program [12]. SHELXTL software package is used to visualize the structure.

3. Results and Discussions

The main crystallographic data and the results of structure refinement are given in Table 1, the main bond lengths and bond angles are in Table 2, and the structure of the complex is shown in Figure 1.

The thermal behavior of the free ligand (Figure 2) and the complex (Figure 3) was studied by the derivatographic method with recording the TG curve. Several thermal manifestations are observed on the DTA curve of the ligand: endothermic—65˚C, 75˚C, 215˚C and exothermic effect at 360˚C, which correspond to the removal of adsorbed moisture, melting, decomposition and burnout of the organic part.

Figure 1. The structure of [Co(L)6]2+ cation complex.

Table 1. Crystallographic characteristics, details of the experiment and refinement of the structure of the compound [Co(L)6](NO3)2.

Table 2. Selected bond lengths (Å) and bond angles (degrees) in the structure [Co(L)6](NO3)2.

Figure 2. С3H4N2 complex thermogram.

Figure 3. [Co(L)6](NO3)2 complex thermogram.

The TG curve of the complex records three stages of weight loss. The first (70˚C - 170˚С) corresponds to the removal of weakly bound guest water molecules. The second (220˚C - 445˚C), due to the actual thermal destruction of the complex, reflects the most intense weight loss (50.00%). Differentiation of the TG curve made it possible to establish that the maximum rate of weight loss falls on 300˚C. Subsequent, weakly expressed stages are associated with the desorption of thermolysis products. The residual product is CoO.

Based on the study of the IR spectrum of pure imidazole (Figure 4), it was revealed that stretching vibrations of the cyclic C=N and C-N bonds of the imidazole molecule correspond to a series of absorption bands in the frequency range 1670 - 1577, 1543 - 1261, and 1261 - 1324 cm–1. The appearance of high-frequency absorption bands at 1668 and 1577 cm–1 is due to stretching vibrations of C-N bonds of the imidazole ring. Intense bands at 1495, 1482, 1447, 1325, 1055 cm−1 correspond to stretching vibrations of the imidazole ring. Bands within 1261 - 940 cm–1 are characteristic of deformation vibrations of C-C, N-C and C-H groups. Strong bands in the range of 740 - 890 cm–1 correspond to out-of-plane deformation vibrations of C-H groups.

In the IR spectrum of the complex (Figure 5), changes occur in the region of vibrations of the main functional groups: the absorption bands of stretching vibrations of conjugated bonds ν (C = C) and ν (C = N) disappear, a high-frequency shift occurs by (25 - 30 cm−1), the intensity of the stretching vibration of the

Figure 4. IR spectrum of imidazole.

Figure 5. IR absorption spectrum of [Co(L)6](NO3)2 complex.

azole ring at 1480 - 1580 cm−1 and new frequencies ν (co-N) appear at 455 - 590 cm−1. From this, it follows that the complex undergoes monodentate coordination of the imidazole molecule through the pyridine nitrogen atom N(3), which is confirmed by X-ray diffraction data.

The crystal and molecular structure of the [Co(L)6](NO3)2 complex, which crystallizes in the trigonal system with the space group R-3, has been determined by X-ray diffraction. The lattice parameters are: a = 12.3555(10), b = 12.3555(10), c = 14.4833(3) Ǻ; α = 90˚, β = 90˚; γ = 120˚; V = 1914.78(5) Ǻ, Z = 3 (Table 1). The structure of the complex consists of discrete [Co(L)6]2+ cations and NO 3 anions. The Co2+ ion has a centrosymmetric octahedron configuration with a coordination site—CoN6 (Figure 1). Imidazole ligand molecules are coordinated through the pyridine nitrogen atom N(3) to the Co2+ ion with an average Co···N bond distance of 2.1590 Ǻ.

In the octahedral complex [Co(L)6](NO3)2 three trans angles are 180˚ in symmetry, and the remaining angles vary from 88.24(2) to 91.76(2)˚ (Table 2). The Co-N bond distance is as follows: a short Co(1)-N(1) bond = 2.1588(6) and a long Co(1)-N(1) bond = 2.1592(2). The chelate cycle of the complex is flat, with an average deviation of 0.0015(2) Ǻ. Opposite imidazole rings are centrosymmetric. Adjacent imidazole rings are almost perpendicular to each other with dihedral angles of 85.25(2), 91.75(2), and 88.25(2)˚, which minimizes steric effects between these rings. In the crystal structure, all imidazole N-H groups, nitrate ions contribute to the formation of hydrogen bonds. The number of intermolecular contacts with a hydrogen bond, including N-H groups and NO 3 anions, connect the cations into layers in the ab plane. The [Co(C3H4N2)6]2+ cations, in turn, are linked by NO 3 anions, forming a three-dimensional network of hydrogen bonds, which stabilizes the crystal structure of the [Co(C3H4N2)6](NO3)2 complex.

4. Conclusion

In summary, we determined structure of [Co(L)6](NO3)2 complex, in which number of intermolecular contacts with a hydrogen bond, including N-H groups and NO 3 anions, connect the cations into layers in the ab plane. Imidazole ligand molecules are coordinated through the pyridine nitrogen atom N(3) to the Co2+ ion. As a result of biological screening, it was established that the [Co(L)6](NO3)2 complex has a fungicidal effect on the Candida bacterial culture. The development is protected by a patent of the Kyrgyz Republic (No. 2211 dated June 9, 2020).

Cite this paper: Alamanova, E. , Shyytyeva, N. , Berdalievа, Z. , Abdyldaeva, N. , Duishonbaeva, A. and Abdullaeva, Z. (2021) Coordination Polymer of Cobalt (ΙΙ) Nitrate with Imidazole: Synthesis, Properties and Crystal Structure. Journal of Crystallization Process and Technology, 10, 1-9. doi: 10.4236/jcpt.2021.101001.
References

[1]   Reiss, A., Cioateră, N., Dobrițescu, A., Rotaru, M., Carabet, A.C., Parisi, F., Gănescu, A., Dăbuleanu, I., Spînu, C.I. and Rotaru, P. (2021) Bioactive Co(II), Ni(II), and Cu(II) Complexes Containing a Tridentate Sulfathiazole-Based (ONN) Schiff Base. Molecules, 26, Article No. 3062.

[2]   Gaber, A., Refat, M.S., Belal, A.A.M., El-Deen, I.M., Hassan, N., Zakaria, R., Alhomrani, M., Alamri, A.S., Alsanie, W.F. and Saied, E.M. (2021) New Mononuclear and Binuclear Cu(II), Co(II), Ni(II), and Zn(II) Thiosemicarbazone Complexes with Potential Biological Activity: Antimicrobial and Molecular Docking Study. Molecules, 26, Article No. 2288.

[3]   Saltykova, M.S., Yelchischeva, Y.B., Chekanova, L.G., Mokrushin, I.G. and Pavlov, P.T. (2020) Complex Forming Properties of Diacylhydrazines of Neopentanic Acid with Ions Cu (II), Co (II) and Ni (II) in Ammonia Media. Perm University Bulletin, Series: Chemistry, 10, 159-168.
https://doi.org/10.17072/2223-1838-2020-2-159-168

[4]   Razzoqova, S.R., Kadirova, S.А., Ashurov, J.M., Rakhmonova, D.S., Ziyaev, A.А. and Parpiev N.A. (2019) 5-(3-hydroxyphenyl)-1,3,4-oxadiazole-2(3H)-thione Hemi-Hydrate. Journal the International Union of Crystallography (IUCr) Data, 4, Article ID: x1915322019.
https://doi.org/10.1107/S2414314619015323

[5]   Bureekaew, S., Shimomura, S. and Kitagawa, S. (2008) Chemistry and Application of Flexible Porous Coordination Polymers. Science and Technology of Advanced Materials, 9, Article ID: 014108.
https://doi.org/10.1088/1468-6996/9/1/014108

[6]   Luconi, L., Tuci, G., Yakhvarov, D., Poli, G., Rossin, A., Khusnuriyalova, A. and Giambastiani, G. (2019) Imidazole-Bridged Tetrameric Group (IV) Heteroleptic Complexes from the Spontaneous Metal-Ligand Assembly of a Potentially N4-Tetradentate Ligand. European Journal of Inorganic Chemistry, 2019, 4384-4393.
https://doi.org/10.1002/ejic.201900763

[7]   Anosov, V.Y., Ozerova, M.I. and Fialkov, Y.A. (1976) Fundamentals of Physical and Chemical Analysis. AN SSSR, Nauka, Moscow, Leningrad, 503 p.

[8]   Emhoff, K.A., Balaraman, L., Simpson, S.R., Stromyer, M.L., Kalil, H.F., Beemiller, J.R., Philipp, S., Teya, S.E., Ahmed, M.H.S., Michael, A.D., Matthew, J.P., Wiley, J.Y. and Christopher, W.B. (2018) Synthesis and Characterization of Cobalt (II) N,N’-Diphenylazodioxide Complexes. ACS Omega, 3, 16021-16027.
https://doi.org/10.1021/acsomega.8b01200

[9]   Bruker (2019) APEX ΙΙΙ. Bruker AXS Inc., Madison, Wisconsin, USA.

[10]   Krause, L., Herbst-Irmer, R., Sheldrick, G.M. and Stalke, D. (2015) Comparison of Silver and Molybdenum Microfocus X-Ray Sources for Single-Crystal Structure Determination. Journal of Applied Crystallography, 48, 3-10.
https://doi.org/10.1107/S1600576714022985

[11]   Sheldrick, G.M. (2015) SHELXT Integrated Space-Group and Crystal-Structure Determination. Acta Crystallography, A71, 3-8.
https://doi.org/10.1107/S2053273314026370

[12]   Sheldrick, G.M. (2015) Crystal Structure Refinement with SHELXL. Acta Crystallography, 71, 3-8.

 
 
Top