A New 3 D Coordination Polymer of Bismuth with Nicotinic Acid N-Oxide

The new three-dimensional coordination polymer {[Bi(NNO) 2 (NO 3 )]⋅1.5H 2 O} n (1, NNO = nicotinate N-oxide) was synthesized and characterized by elemental analysis, IR and H-NMR spectroscopy, as well as single-crystal X-ray diffraction analysis. 1 crystallizes in the monoclinic space group C2/c. The crystal structure consists of a rectangular-shaped grid constructed with NNO linkers. Cavities of a diameter of 7.9–8.3 Å2 are filled with disordered water molecules. The thermal stability of the compound was evaluated by thermogravimetric analysis.


Introduction
Metal-organic frameworks (MOFs) have currently attracted ever-increasing attention because of their intriguing structural topologies and promising applications as functional materials in magnetism, sorption [1], separation, catalysis [2], and drug delivery [3].Therefore, there are intense research efforts on the synthesis of such materials, and several metalorganic frameworks with zeolitic structures have been reported [4].With their versatile bridging modes, carboxylates are often employed as building blocks to construct coordination polymers [5].
Pyridyl carboxylic acids and their N-oxide derivatives are especially useful in this regard, but the exploitation of the ligands in the construction of open framework materials is still in its infancy [6][7][8].The anions of these acids may bond to metal centers via their N-and O-donor atoms.Thus, one would expect higher flexibility and more versatile coordination modes compared to the original ligand (Scheme 1).Furthermore, the separation of the bridging sites is definitely larger.However, studies on such ligand behavior toward coordination polymers are limited, and only a few transition metal-, lanthanide metal-, and main group metal-based coordination polymers incorporating pyridyl carboxylic acid Noxides have been structurally examined [9,10].
Herein, we describe the synthesis and characterization of a new 3D coordination polymer with nicotinate N-oxide (NNO), {[Bi(NNO) 2 (NO 3 )]⋅1.5H 2 O}  (1).To the best of our knowledge, no systematic investigation of bismuth-based compounds [11] with nicotinic acid N-oxide has been documented [12].(1).All reagents were used as purchased without further purification.Nicotinic acid N-oxide (0.104 g, 0.75 mmoL) was placed in one of the arms of a branched tube [13], whereas bismuth(III) nitrate pentahydrate (0.121 g, 0.25 mmoL) was placed in the other arm.Methanol and water (ratio 3 : 1) were carefully added to fill both arms.The tube was sealed and the ligand-containing arm was immersed in a bath at 60 ∘ C, whereas the other maintained at ambient temperature.After two days, crystals that had been deposited in the cooler arm were filtered, washed with acetone and ether, and dried in air (yield: 85%).
Data collection for X-ray diffraction single crystal structure determination was performed on a Stoe IPDS 2T diffractometer using graphite-monochromated MoK radiation (0.71073 Å).The data were corrected for Lorentz and polarization effects.A numerical absorption correction based on crystal-shape optimization was applied for all data [14].The programs used in this work are Stoe's X-AREA [15], including X-RED and X-SHAPE for data reduction and absorption correction [16], and the WINGX suite of programs [17], including SIR-92 [18] and SHELXL-97 [19] for structure solution and refinement.The hydrogen atoms were placed in idealized positions and constrained to ride on their parent atoms.The last cycles of refinement included atomic positions for all atoms, anisotropic displacement parameters for all nonhydrogen atoms, and isotropic displacement parameters for all hydrogen atoms.Full cif deposition, excluding structure factor amplitudes, was resided by the Cambridge Crystallography Data CCDC-906828 for 1, and copies of the data can be obtained, free of charge, via http://www.ccdc.cam.ac.uk/deposit.

Results and Discussion
Colourless block-shaped crystals of {[Bi(NNO) 2 (NO 3 )]⋅ 1.5H 2 O}  (1) were obtained by slow interdiffusion of solutions of Bi(NO 3 ) 3 ⋅5H 2 O and nicotinic acid N-oxide (HNNO) in aqueous methanol under ambient conditions.The crystal structure of 1 may be regarded as a three-dimensional coordination polymer.The coordination environment around the Bi 3+ ion is shown in Figure 1 together with the asymmetric unit of the crystal structure; selected interatomic distances are summarized in Table 1.The bismuth ions center slightly distorted tricapped trigonal prisms with two oxygen atoms of one nitrate anion and seven oxygen atoms of five nicotinate N-oxide anions with Bi-O distances between 2.323(2) and 2.816(3) Å [20] (sum of the ionic radii Bi 3+ and O 2− is 2.43 Å).
In 1, five unique NNO − anions adopted two different types of coordination modes, as shown in Figure 2  Table 2: Hydrogen bonding in the crystal structure of (1).
2.983 (8) Encapsulated in the Bi(III)-NNO framework, there are uncoordinated, disordered water molecules in the crystal structure of 1.The bridging NNO − ligands are arranged in conjunction with weak - stacking interactions of the pyridine rings (distances between the rings are 3.440 Å) [23].The rectangular-shaped grid, formed by NNO − anions and bismuth ions, gives rise to the large rectangular cavities known among noninterpenetrating structures [24], with approximate cavity sizes of 7.9-8.3Å2 .One and a half crystallographically unique water molecules are trapped within these channels.As shown in Figure 2, uncoordinated water molecules and the carboxylate oxygen atoms of the NNO − ligands are involved in hydrogen bonding interactions (Table 2).The topology of the three-dimensional bismuth(III)-coordination polymer may be characterized (by TOPOS program) by the point symbol for the net as follows: {3 3 .4 5.5 6 .6}.
Thermogravimetric analysis (TGA) was performed applying polycrystalline samples under nitrogen atmosphere to get an idea of the thermal stability of {[Bi(NNO) 2 (NO 3 )]⋅ 1.5H 2 O}  (1), see (Figure 3).The first weight loss at 85-115 ∘ C in the TG curve corresponds to the loss of water molecules (calcd.4.70%).Decomposition of the framework is characterized by an intense exothermic peak (270 ∘ C) followed by another weak exothermic peak (320 ∘ C).Accordingly, a rapid mass loss occurs between 270 and 350 ∘ C in the TG curve corresponding to 50% of the original sample mass.Coordination polymer 1 appears to decompose completely during this transition, presumably leaving a final residue of Bi 2 O 3 (found 41.20%, calcd.40.59%).The mass loss calculations as well as the microanalyses (atomic absorption) of the solid residues suggest that the residue left as a final decomposition product of the complexes is Bi 2 O 3 .IR analysis of the final residue (at 700 ∘ C) revealed none of the characteristic absorption bands of 1.In addition, the presence of absorption peaks at 421, 500, 541, and 845 cm −1 in the IR spectrum provides evidence for the identity of the residue as Bi 2 O 3 [25].

Conclusions
In this paper, with {[Bi(NNO) 2 (NO 3 )]⋅1.5H 2 O}  (NNO − = nicotinate N-oxide, 1), a new three-dimensional coordination polymer is reported.Channels are formed by bridging of the NNO − ligands, representing a new coordination mode.Uncoordinated and disordered water molecules are trapped within the rectangular channels.These water molecules and the carboxylate O-atom of the NNO − ligands are involved in hydrogen bonding interactions.This three-dimensional coordination polymer appears to represent the first crystal structure of bismuth(III) with nicotinic acid N-oxide.

Figure 2 :
Figure 2: (a) View of the three-dimensional coordination polymer in the crystal structure of 1 along the crystallographic  axis.The guest water molecules are located within the rectangular channels.(b) Bi−Bi distances and the coordination modes of the NNO − anions in 1.