Transition Metal Complexes: Bonding and Spectra

Prerequisite: Valence bond theory.

Crystal Field Theory- Important postulates, crystal field splitting of d-orbitals in octahedral and tetrahedral complexes, factors affecting the magnitude of  Δ_0, calculation of crystal field stabilization energy, strong and weak ligands, spectrochemical series, distribution of d-electrons in t_2g and e_g 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.

Prerequisite: Types of magnetism.               

Types of magnetic behaviour, methods of determining magnetic susceptibility, spin only formula, correlation of μ_s 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, trans-effect, theories and its uses, mechanism of substitution reactions in square planar complexes, trans-effect, theories of trans-effect and its uses.