To learn the nature of metal-ligand bonding in coordination compounds and understand the magnetic and spectral aspects of transition metal complexes and their applications.
Pre requisite: Valence bond theory.
Limitations of VBT, crystal field theory- important postulates, crystal field splitting of d-orbitals in octahedral and tetrahedral complexes, factors affecting the magnitude of Δ0, calculation of crystal field stabilization energy; strong and weak ligands, spectrochemical series; distribution of d-electrons in t2g and eg orbitals in octahedral and tetrahedral complexes.
Distortion of octahedral complexes, crystal field splitting of d-orbitals in square planar complexes and Jahn Teller theorem; use of CFSE values, number of unpaired electrons and high spin (HS) and low spin (LS) complexes,applications and limitations of CFT.
Pre requisite: Types of magnetism.
Types of magnetic behaviour, methods of determining magnetic susceptibility, spin only formula, correlation of μs and μ eff values; orbital contribution to magnetic moments, applications of magnetic moment data for 3d-complexes
Types of electronic transitions; coupling of orbital angular momenta and spin angular momenta (in p2 and d2 configuration), spin orbit coupling/LS coupling, determining the ground state terms – Hund’s rule, hole formulation, calculation of the number of micro states; selection rules- Laporte ‘orbital’ selection rule, spin selection rule, spectroscopic ground states; Orgel energy level diagram for d1-d9 states, discussion of electronic spectrum of [Ti(H2O)6]+3 complex.
Definition of stability, stepwise and overall formation constants, kinetic v/s thermodynamic stability, labile and inert complexes, factors affecting the stability of complexes; the ligand substitution reactions in square-planar complexes, the trans-effect, theories of trans-effect and its uses.