One the basis of `VBT` answer the following complex ions
`[Ti(bpy)_(3)]^(Θ)`
(a) Type of hybridisation involed
(b) Type of inner or outer orbital octahedral complex
(c ) Magnetic behaviour and `mu_(spin)` value .

Using valence bond theory, explain the following in relation to the complexes given below [Mn(CN)_(6)]^(3-), [Co(NH_(3))_(6)]^(3+), [Cr(H_(2)O)_(6)]^(3+), [FeCl_(6)]^(4-) (a) type of hybridisation (b) Inner or outer orbital complex (c) Magnetic behaviour (d) Spin only magnetic moment value.

For the complex ion [Fe(CN)_(6)]^(3-) , state : (i) the type of hybridisation. (ii) the magnetic behaviour. (iii) the oxidation number of the central metal atom.

What are the types of hybridization involved in the following geometrical shapes of the complex? (a) square planar (b) Tetrahedral (c) Octahedral

On the basic VBT answer the following questions for the 4-coordinated complex compounds [CoBr_(4)]^(2-) (i) What is the oxidation state of the central metal atom//ion? (ii) What type of hybridisation is involved? (iii) What is the geometry and magnetic behaviour of the complex ion/compound

In which of the following complex ion the value of magnetic moment (spin only) is sqrt(3) B.M. and oute rd-orbitals is used in hybridization:

Nickel chloride, when treated with dimethyl gyloxime in presence of ammonium hydroxide, a bright red precipitate is obtained. Answer the following: (a) Draw the structure of the complex showing H-bonds (b) Give oxidation state of nickel and its hybridization (c) Predict the magnetic behaviour of the complex

With reference to the coordination compler ion [Fe(H_(2)O)_(6)]^(2+) answer the following: (at. no. of Fe=26) State the type of hybridisation of the complex ion.

Velence bond theroy describes the bonding in complexs in terms of coordinate -covalent bond resulting from overlap filled ligand orbitals with vacant metal hybrid orbitals This theory explains magnetic behaviour and geometrical shape of coordination compounds Magnetic moment of a complex compound can be determined experimentally and theoretically by using spin only formula Magnetic moment sqrtn (n+2)BM (where n = No. unpaired electrons) . The value of of spin only magnetic moment for octahedral complex of the following configuration is 2.84BM The correct statement is (a) d^(4) (in weak field ligand) (b) d^(2) (in weak field and in strong field ligand) (c) d^(3) (in weak field and in strong field ligand) (d) d^(5) (in strong field ligand) .

Velence bond theroy describes the bonding in complexs in terms of coordinate -covalent bond resulting from overlap filled ligand orbitals with vacant metal hybrid orbitals This theory explains magnetic behaviour and geometrical shape of coordination compounds Magnetic moment of a complex compound can be determined experimentally and theoretically by using spin only formula Magnetic moment sqrtn (n+2)BM (where n = No. unpaired electrons) . Ni^(2+) cation combines with a uninegative monodentate ligand X^(Θ) to form paramagnetic complex [NiCI_(4)]^(2-) The number of unpaired electrons(s) in central metal cation and geometry of this complex respectively are (a) One,tetrahedral (b) Two,tetrahedral (c ) One,square planar (d) Two, square planar .

Ni^(+2) form a complex inon in water having the formula [Ni(H_(2)O)_(6)]^(+2) . How many of the following statement are true for the complex ion ? (i) The complex is octahedral in shape (ii) The complex is diamagnetic in nature . (iii) Ni^(+2) has incompletely filled 3d subshell. (iv). Secodary valency of Ni^(+2) is 6 (v) All the bonds (metal-ligand ) are perpendicular to each other. (vi) All the 3d orbitals of Ni^(+2) are degenerate (vii) Total spin of the complex is 1. (viii) The hybridisation of Ni^(+2) is d^(2)sp^(3) (ix) The complex is more stable than [Ni(en)_(3)]^(+2) (x) Effective atomic number of Ni^(+2) is 36.