π What Are Coordination Compounds? π
- Coordination compounds consist of a central metal atom/ion bonded to ligands via coordinate covalent bonds.
- Ligands are ions or molecules that donate electron pairs to the metal atom/ion.
π§° Key Terms in Coordination Compounds π§°
- Coordination Number (C.N.):
- The number of ligands directly attached to the central metal atom/ion.
- Example: In [Fe(CO)β ], C.N. = 5.
- Ligands:
- Molecules or ions that can donate electron pairs to the central metal.
- Types of Ligands:
- Monodentate: Can donate one pair of electrons (e.g., Clβ», HβO).
- Bidentate: Can donate two pairs of electrons (e.g., ethylenediamine).
- Polydentate: Can donate multiple pairs of electrons (e.g., EDTA).
π§ͺ Wernerβs Theory π§ͺ
- Wernerβs Theory explains the structure and bonding of coordination compounds.
- Primary valency: The number of bonds formed between the metal ion and the anions.
- Secondary valency: The number of bonds formed between the metal and ligands.
- Example:
- In [CoClβΒ·6HβO], cobalt forms 6 bonds with water molecules and 3 bonds with chloride ions.
π‘ Valence Bond Theory (VBT) π‘
- Valence Bond Theory explains coordination compound bonding in terms of hybridization.
- Central metal atoms use d, s, and p orbitals to form hybrid orbitals and bond with ligands.
- For example, [Ni(CO)β]: The central NiΒ²βΊ undergoes spΒ³ hybridization to form bonds with 4 CO ligands.
- Important Features:
- Metal atoms undergo hybridization to maximize bonding.
- Ligands act as electron pair donors, forming coordinate bonds.
π Crystal Field Theory (CFT) π
- Crystal Field Theory describes how ligands interact with d-orbitals of the central metal atom.
- Ligand field splitting occurs, resulting in the splitting of d-orbitals into two energy levels.
- The degree of splitting depends on the geometry of the complex (e.g., octahedral, tetrahedral).
- Example:
- In [Cu(NHβ)β]Β²βΊ, the d-orbitals split into two energy levels due to the interaction with NHβ ligands.
β‘ Applications of Coordination Compounds β‘
- Catalysis:
- Coordination compounds are used as catalysts in industrial processes (e.g., Haber process for ammonia synthesis).
- Biological Systems:
- Haemoglobin, a coordination compound, helps in oxygen transport in the human body.
- Medicinal Uses:
- Cisplatin, a coordination complex of platinum, is used as a chemotherapy drug.
- Dyes and Pigments:
- Coordination compounds are used to make coloured dyes and pigments (e.g., Prussian blue).
π Conclusion π
- Coordination compounds play a crucial role in various fields such as medicine, catalysis, and biological systems.
- The bonding in coordination compounds is explained by Wernerβs theory, Valence Bond theory, and Crystal Field theory, which describe the nature of interactions between metal atoms and ligands.