Research Journal of Chemical Sciences ______________________________________________ ISSN 2231-606X Vol. 4(12), 34-38, December (2014) Res. J. Chem. Sci.International Science Congress Association 34 Synthesis and Characterization of Co (Ii) And Ni (Ii) Complexes of 2, 5-Substituted 1, 3, 4-Oxadiazole DerivativesSubha C and Selvaraj A Department of Chemistry, CBM College, Coimbatore-641 042, INDIA Available online at: www.isca.in, www.isca.me Received 10th November 2014, revised 8th December 2014, accepted 15th December 2014 AbstractEight new Co(II) and Ni(II) complexes with variously substituted 1,3,4-oxadiazoles (L-L) have been prepared and characterized by magnetic susceptibility, molar conductance, molecular weight determination and spectral studies. All the cobalt complexes exhibit the composition Co(L)Cl.2HO and the formula Ni(L)(SO). 2HO has been assigned to Ni(II) complexes. Although 1,3,4-oxadiazoles have three coordinating sites, namely two ring nitrogen and one oxygen, the spectral studies indicate that only the two ring nitrogen involved in the coordination. Electronic spectral data reveal that theses complexes have octahedral geometry. Keywords: Complexes, 1,3,4-oxadiazole, magnetic property, octahedral geometry. IntroductionThe coordination chemistry of Co(II) and Ni(II) are well established and they form complexes with a variety of organic ligands. 1,3,4 – Oxadiazole, considered as an important five member compound among the huge heterocyclic families, has been studied as an excellent candidate for material applications during the past years due to its excellent thermal, chemical stabilities and high photoluminescence quantum yields. These properties combined with its electron deficient nature and good electron accepting ability, have led to many potential applications in organic light emitting diodes1-3 The wide range of applications of the ligand and its metal complexes are used our interest to prepare a new series of some of those metal complexes. We describe in this paper, the synthesis and characterization of Cobalt(II) and Ni(II) complexes with eight differently substituted 1,3,4- Oxadiazoles. Material and Methods Reagents: The variously substituted 1, 3, 4-Oxadiazoles (L-L) were prepared, following the reported procedures 4. Purified EtOH (95%) was used as solvent. Cobalt (II) chloride and Nickel (II) sulphate was of Analar grade. Synthesis of metal complexes: A solution of [M (II)] salt [Cobalt (II) chloride for Co (II), Nickel (II) sulphate for Ni (II)] (5mmol) in ethanol (30ml) was added to a solution of Oxadiazole (15 mmol) in ethanol (30ml) and the mixture was boiled under reflux on a water bath for 3 – 4hrs. The solvent was then removed by vacuum distillation and the pasty residue was thoroughly washed with acetone and dry ether to remove unreacted M(II) and oxadiazole. The complex obtained was dried over P in vacuum. Physical measurements: Molecular weight determinations were carried out by the freezing point depression method, using camphor as solvent. The metal content of each complex was estimated by complexometric EDTA titration5,6 using xylenol orange as an indicator. Conductance measurements were performed on 10-3 mol dm-3 solutions of the complexes in acetonitrile using CM-82 Eli co Digital Conductivity meter with a dip type conductivity cell fitted with platinum electrodes. (Cell constant = 1.0 cm-1). The effective magnetic moments of the complexes were determined by Guoy method at room temperature. The IR spectra of the ligands and the complexes were recorded on Shimadzu FT-IR 8000 spectrophotometer in the 4000 – 400 cm-1 region using the KBr disc technique. Results and Discussion The colour of the cobalt (II) oxadiazole complexes ranges from yellow to dark brown whereas the colour of the Nickel (II) oxadiazole complex ranges from yellow to Orange. All the complexes were found to be solids, insoluble in water and soluble in ethanol, DMSO, Acetonitrile etc., the complexes were non-hygroscopic and stable in air. A perusal of the conductivity values for the complexes of Ni(II)-oxadiazole reveals that all the complexes synthesized have very low conductivities in the range of 10-6mho. Conductivity studies: The molar conductance values of cobalt (II) chloride complexes are found to be in the range of 10-6 mho indicating that these complexes are non-electrolytes. This observation suggests that the complex molecule is neutral with the sulphate ions held tightly within the coordination sphere along with the oxadiazole ligands. Research Journal of Chemical Sciences ___________________________________________________________ ISSN 2231-606XVol. 4(12), 34-38, December (2014) Res. J. Chem. Sci.International Science Congress Association 35 Table-1 The structures of the synthesized ligands are as follows ONN NH 2-Phenyl 5-amino 1,3,4-oxadiazole ONN OCH 2 2’-methoxy phenyl 5-amino 1,3,4-oxadiazole ONN Cl 2’-chlorophenyl5-amino 1,3,4-oxadiazole ONN OH 2’-hydroxyphenyl5-amino 1,3,4-oxadiazole O N N CH 2’-methylphenyl 5-amino 1,3,4-oxadiazole O N N NO 2’-nitrophenyl 5-amino 1,3,4-oxadiazole ONN H2N OHOCH 3’-methoxy-4’-hydroxyphenyl5-amino 1,3,4-oxadiazole ONN H2N NO 3’-nitrophenyl5-amino 1,3,4-oxadiazole Molecular weight determination: The observed molecular weights of all the complexes show that one metal atom co-ordinates with two oxadiazole ligand molecules indicating that they behave as 1:2 non-electrolyte. The results of both molar conductance studies and molecular weight determinations complement each other. The most probable molecular formulae of complexes studied in this work are derived from the metal content and the corresponding experimental molecular mass. The molecular formula for the cobalt (II) oxadiazole and Ni (II) oxadiazole complexes, their molecular weight, Conductivity, colour and Magnetic moment are given in Table 1 and 2 respectively. Magnetic Properties: The effective magnetic moments(µeff) of Cobalt(II) and Nickel(II) complexes were calculated from their magnetic susceptibilities obtained by Guoy’s method and the data are given in table-2 and 3 respectively. The µeff values of Cobalt (II) complexes are found to be in the range of 4.13-6.68 BM. These values are in agreement with the high spin dcomplexes. For Ni (II) complexes, when the values of µeff are compared with µobs, value, the µobs values are higher than µeff. The µobs value ranges from 4-5 BM. This may be due to the following reasons the orbital angular momentum is quenched for (t2g 6 (e 2 configurations, spin-orbit coupling is greater because of positive quantity of , and negative quantity of . Hence the observed magnetic moment is higher than the predicted magnetic moment. These higher values are in accordance with high spin d complex. IR spectral studies: The IR spectra of the ligands were compared with those of the cobalt (II) complexes in order to confirm the binding mode of the 2, 5-disubstituted 1, 3, 4-oxadiazoles ligands to the cobalt (II) ion in the complexes. The characteristic IR bands of the complex differ from free ligand providing significant indications about the co-ordination and bonding sites of the ligand. FTIR spectral analysis of Research Journal of Chemical Sciences ___________________________________________________________ ISSN 2231-606XVol. 4(12), 34-38, December (2014) Res. J. Chem. Sci.International Science Congress Association 36 complexes in general reveals that C=N stretching has shifted from 1511 to 1548 cm-1. The upward shift in the C=N stretching frequency indicates the formation of coordinate covalent bond involving the nitrogen of azomethine group C=N with the metal atom. IR spectra of the complexes synthesized in the present studies indicate the absence of the three additional vibrational modes that would have arisen had there been an M-OH bond. Hence it can be concluded that all the complexes synthesized in the present investigation do not contain HO molecule within the coordination sphere. Cobalt (II) complexes show an absorption band at 265cm-1 which proves beyond doubt that the existence of M-Cl bond in the complexes and the presence of Cl inside the co-ordination sphere. For Ni (II) oxadiazole complexes, the appearance of a strong absorption band at 1580-1600cm-1 is due to (C=N). The coordination of the azomethine nitrogen to the metal center was confirmed in the IR spectra of the complex by a shift of the (C=N) band to lower frequency. Additional evidence for the coordination of the azomethine nitrogen is the presence of (M-N) bands in the frequency range of 300-500cm-1. The IR spectral absorption band values of Co (II) and Ni (II) oxadiazole complexes are given in tables-4 and 5 respectively. Table-2 Physical and Analytical data of Co (II) – Oxadiazole complexes Complex formula Molecular Weight found (theot.) (Cal) Conductivity v X 10-6Colour Magnetic moment µ X10-2 [Co(L2 Cl].2HO 486.83 (511.8) 08.51 Light Brown 6.68 [Co(L2 Cl].2HO 536.83 (548.23) 12.50 Dirty Yellow 4.36 [Co(L2 Cl].2HO 555.83 (541.29) 10.53 Dirty Yellow 6.05 [Co(L2 Cl].2HO 518.83 (503.70) 32.60 Dark Brown 5.24 [Co(L2 Cl].2HO 515.83 (515.83) 14.90 Brown 4.94 [Co(L2 Cl].2HO 577.83 (579.96) 17.19 Brown 5.71 [Co(L2 Cl].2HO 579.83 (553.56) 25.90 Pale Brown 4.69 [Co(L2 Cl].2HO 577.83 (553.01) 15.22 Yellow 4.13 Table-3 Physical and Analytical data of Ni (11) – Oxadiazole complexes Complex formula Molecular Weight found (thert) (Cal) Conductivity v X 10-6Colour Magnetic moment µ X10-2 [Ni(L 1 ) 2 (SO 4 ) 2 ].2H 2 O 512.71 (502.02) 03.70 Yellow 5.30 [Ni(L 2 ) 2 (SO 4 ) 2 ].2H 2 O 572.71 (585.06) 07.58 Dirty yellow 4.87 [Ni(L 3 ) 2 (SO 4 ) 2 ].2H 2 O 580.71 (585.06) 08.55 Pale orange 4.96 [Ni(L 4 ) 2 (SO 4 ) 2 ].2H 2 O 544.71 (535.99) 16.75 Dark brown 4.69 [Ni(L 5 ) 2 (SO 4 ) 2 ].2H 2 O 540.71 (541.29) 11.70 Dark orange 5.64 [Ni(L 6 ) 2 (SO 4 ) 2 ].2H 2 O 602.71 (593.10) 15.21 Orange 5.53 [Ni(L 7 ) 2 (SO 4 ) 2 ].2H 2 O 604.71 (586.23) 12.18 Pale brown 5.29 [Ni(L 8 ) 2 (SO 4 ) 2 ].2H 2 O 602.71 (604.51) 07.14 Light yellow 5.61 Table-4 IR absorption bands (in cm-1) of the ligands and Co (II)-Oxadiazole complexes Name of the complex (C=N) (C=N)b (-NH) Aromatic (=C-H) (O-H) water of crystallization (M-Cl Co-L 1 1511 1605.34 3460.23 3065.52 3287.51 278 Co-L 2 1510.11 1593.89 3469.20 3061.77 3281.74 265 Co-L 3 1594.02 1619.96 3464.26 3070.29 3278.09 261 Co-L 4 1529.82 1548.03 3469.11 3062.96 3286.41 301 Co-L 5 1511.14 1548.08 3467.23 3066.78 3203.47 273 Co-L 6 1535.94 1556.00 3452.67 3001.75 3203.83 269 Co-L 7 1513.49 1522.16 3462.35 3077.08 3238.08 264 Co-L 8 1513.28 1593.78 3463.41 3069.87 3278.16 264 -for free ligand, -for complexes Research Journal of Chemical Sciences ___________________________________________________________ ISSN 2231-606XVol. 4(12), 34-38, December (2014) Res. J. Chem. Sci.International Science Congress Association 37 Table-5 IR absorption bands (in cm-1) of the ligands and Ni (II)-Oxadiazole complexes Name of the complex (C=N) (C=N)b (-NH) Aromatic (=C-H) (O-H) water of crystallization (M-SO2- Ni-L 1 1511 1605.68 3460.45 3064.26 3281.74 1029.22 Ni-L 2 1510.11 1594.08 3474.26 3061.74 3280.94 1032.24 Ni-L 3 1594.02 1609.56 3464.24 3074.34 3276.09 1012.85 Ni-L 4 1529.82 1600.90 3489.93 3026.75 3277.89 1036.73 Ni-L 5 1511.14 1535.89 3467.12 3063.13 3273.17 1030.64 Ni-L 6 1535.94 1557.76 3466.89 3000.10 3203.01 1022.87 Ni-L 7 1513.49 1522.27 3463.80 3071.95 3287.99 1040.40 Ni-L 8 1513.28 1590.45 3463.73 3067.39 3278.72 1067.77 -for free legend, -for complexes UV spectral studies: To understand the UV-visible spectral behaviour of Cobalt (II)-oxadiazole complexes, typical spectrum of Cobalt (II)-L complex has been recorded and interpreted. The UV-visible spectrum of Co(II)-L complex contains one well resolved absorption band around 8500cm-1and a multiple absorption band around 21,000 cm-1. The absorption band observed around 8500cm-1 for the cobalt (II)-Lcomplex can be assigned to 1g 2g transition. The multiple band observed around 21,000cm-1 can be assigned to the two transitions, viz, 1g 2g (), 1g 2g (P) () and the third are to the spin-orbit coupling effects or transitions to doublet state. The three absorption bands noticed for the Nickel (II)-Lcomplex in the present studies can be assigned to 2g 2g= 9,000cm-1), 2g 1g (F) (=17,000cm-1) and 2g 1g (P) (= 28,000cm-1). Table-6 Electronic Absorption Spectral data for Metal (II)-complexes Complex 1 (cm - 1 ) 2 (cm - 1 ) 3 (cm - 1 ) Cobalt(II)-L 8,500 Multiple absorption band around 21,000 Nickel(II)-L 2 9,000 17,000 28,000 Conclusion Based on the foregoing observations, the following conclusions have been drawn: i. All the Cobalt (II) and Nickel (II) oxadiazole complexes synthesized are 1:2 non-electrolytes. ii. Oxadiazole ligand acts as a bidentate ligand. iii. Although, 2,5-disubstituted 1,3,4-oxadiazoles contain three potential co-coordinating sites, namely the two ring nitrogen and the oxygen, it has been shown by IR and UV spectral studies that it is the two ring nitrogen atoms that are involved in complexation and not the oxygen atom. Thus, 2, 5-disubstituted 1, 3, 4-oxadiazoles act as bidentate ligands. iv. IR spectral studies confirm the presence of two water molecules in all the complexes as water of crystallization. v. Magnetic moments and electronic spectra of the complexes reveal that the complexes are spin-free and have octahedral geometry. Figure-1 The most probable structure of Cobalt (II) –oxadiazole complexes Figure-2 The most probable structure of Nickel(II)-oxadiazole complexesReferences 1.Singh Poonam et.al, Der. Chemica.silica; 1(3), 118-123(2010) 2.Chien-Holinet.al., J. Chinese Chem. Soc.,57, 1167-1171 (2010)3.M. Benabdellah et.al, Int. J. Elec. chem. sci.,7, 3489-3500 (2012)4.Parameshwari K, Study of the mechanistic and kinetic aspects of corrosion inhibition of mild steel by oxadiazoles, thiadiazoles and triazoles in acid media, Ph.D Thesis, Bharathiar University, Tamil Nadu, India, (2006) Research Journal of Chemical Sciences ___________________________________________________________ ISSN 2231-606XVol. 4(12), 34-38, December (2014) Res. J. Chem. Sci.International Science Congress Association 38 5.F.J. Welcher, The analytical use of EDTA, Vol.4, Van Nostrand, New York, (1965) 6.A.I. Vogel, A Text book of Inorganic Quantitative Analysis, 3rd Edition, Longmans, London, (1951)7.A.B.P. Lever, Inorganic Electronic Spectroscopy, Elsevier, New York, 480, (1984)