Using the valence bond theory, predict the geometry and magnetic behaviour of `[CoF_(6)]^(3-)`.
(Atomic number of Co = 27)

With the help of valence bond theory, compare the magnetic behaviour of [ Co(NH_(3)]_(6)]^3+ and [ CoF_(6)]^3- complex' ions.

Compare the following complexes with respect to structural shapes of untis, magnetic behaviour and hybrid orbitals involved in units. [CoF_(6)]^(3-) (Atomic number of Ni = 28, Co = 27).

Give the formula of each of the following coordination entities. Ni^(2+) ion is bound to two water molecules and two oxalate ions. Write the name and magnetic behaviour of each of the above coordiantion entities. (Atomic number of, Ni = 28)

deduce the following complexe with respect to structural shapes of untis, magnetic behaviour and hybrid orbitals involved in units. [NiCl_(4)]^(2-) (Atomic number of Ni = 28).

Compare the following complexes with respect to structural shapes of untis, magnetic behaviour and hybrid orbitals involved in units. [Ni(CN)_(4)]^(2-) (Atomic number of Ni = 28, Co = 27).

Dicuss in brief the crystal field theory. How does it differ from valence bond theory? Explain the fact the [CoF_(6)]^(3-) is paramagnetic whereas [Co(NH_(3))_(6)]^(3+) is daimagnetic although both are octahedral.

Using valence bond theory, explain the following in relation to the complexes, given below: [Mn(CN)_(6)]^(3-),[Cr(H_(2)O)_(6)]^(3+) . Magnetic behaviour

Using valence bond theory, explain the following in relation to the complexes, given below: [Mn(CN)_(6)]^(3-),[Cr(H_(2)O)_(6)]^(3+) . Type of hybridisation