s-1: `[MnCl_(6)]^(3),[FeF_(6)]^(3-)` and `[CoF_(6)]^(-3)` are paramagnetic having four, five and four unpaired electrons respectively.
S-2: Valence bond theory gives a quantitative interpreation of the thermodynamic stabilities of coordination compounds.
S-3: The crystal field splitting `Delta_(o)` depends upon the field produced by the ligand and charge on the metal ion. Amongst the following correct statements are :

Give the electronic configuration of the d-orbitals of Ti in [Ti(H_2O)_6]^(3+) ion in an octahedral crystal field.

Assertion : [Fe(H_(2)O)_(6)]^(2+) is sp^(3) d^(2) hybridised and paramagnetic complex ion . Reason : [Fe(H_(2)O)_(6)]^(2+) has four unpaired electrons as H_(2)O is a weak field ligand .

The colour of the coordination compounds depends on the crystal field splitting. What will be the correct order of absorption of wavelength of light of the visible region, for the complexes, [Co(NH_(3)_(6)]^(3+). [Co(CN)_(6)]^(3+). [Co(H_(2)O)_(6)]^(3+)

a) Give the electronic configuration of the d-orbitals of Ti in [Ti(H_2O)_6]^(3+) ion in the octahedral crystal field. b) Why is this complex coloured ? Explain on the basis of distribution of electrons in d-orbitals.

Give the electronic configuration of the following complexes on the basis of crystal field splitting theory. [CoF_(6)]^(3-), [Fe(CN)_(6)]^(4-) and [Cu(NH_(3))_(6)]^(2+) .

The colour of the coordination compounds depends on the crystal field splitting . What will be the correct order of absorption of wavelength of light in the visible region, for the complexes, [Co(NH_(3))_(6)]^(3+) , [Co(CN)_(6)]^(3-) and [Co(H_(2)O)_(6)]^(3+) ?

Consider the following statements: According the Werner's theory. (1) Ligands are connected to the metal ions by ionic bonds. (2) Secondary valencies have directional properties (3) Secondary valencies are non-ionisable Of these statements :

According to C.F.T, attraction between the central metal ion and ligands in a complex is purely electrostatic. The transition metal which forms the central atom cation in the complex is regarded as a positive ion. It is surrounded by negative ligands or neutral molecules which have a lone apir of electrons, if the ligand is a neutral molecule such as NH_(3) , the negative and of the dipole in the molecule is directed towards the metal cation. the electrons on the central metal ion are under repulsive forces from those on the ligands. thus the electrons occupy the d-orbitals remain away from the direction of approach ligands. ltBrgt Q. Correct relationship between pairing energy (P) and C.F.S.E. (Delta_(o)) in

Complex compounds are molecular compounds which retain their identities even when dissolved in water. They do not give all the simple ions in solution but instead furnish complex ions. The complex compounds are often called coordination compounds because certain groups called ligands are attached to the central metal ion by coordinate or dative bonds. coordination compounds exhibit isomerism, both structural and stereoisomerism. the structure, magnetic property, colour and electrical properties of complexes are explained by various theories: Q. Arrange the following compounds in order of their molar conductance: (i) K[Co(NO_(2))_(4)(NH_(3))_(2)] (ii) [Cr(ONO)_(3)(NH_(3))_(2)] (iii) [Cr(NO_(2))(NH_(3))_(5)]_(3)[Co(NO_(2))_(6)]_(2) (iv) Mg[Cr(NO_(2))_(5)(NH_(3))]

The energy required to remove an electron from the outermost shell of an isolate gaseous atom is known as IE_(1) of that atom. Similarly, the enrgy required for the removal of the electron from the unipositive ion, diapositive ion and tripositive ion are known as IE_(2),IE_(3) and IE_(4) respectively, and are called successive ionisation energies. The magnitude of the charge depends on the size of the orbital of electron. Electrons in smaller orbitals are on average close with each other and have more repulsion. Thus for Be(2s^(2)) , the IE_(1) and IE_(2) are 9.3 and 18.2 eV "atom"^(1) , whereas for Ca(4s^(2)) , the values are 6.1 and 11.9 eV . Which of the following are isoelectronic species? 1 rarrCH_(3)^(o+),IIrarrNH_(2)^(ɵ),IIIrarrNH_(4)^(o+),IVrarrNH_(3)