A coordination complex of type `MX_(2)Y_(2)` (M-metal ion: X, Y-monodentate lingads), can have either a tetrahedral or a square planar geometry. The maximum number of posible isomers in these two cases are respectively:

Nickel (Z=28) combines with a uninegative monodentate ligand X^(-) to form a paramagnetic complex [NiX_4]^(2-) . The number of unpaired electron(s) in the nickel and geometry of this complex ion are, respectively:

Homoleptic octahedral complexes of a metal ion ' M^(3+) ' with three monodentate ligands L_(1),L_(2) and L_(3) absorb wavelengths in the region of green, blue and red respectively. The increasing order of the ligand strength is :

Homoleptic octahedral complexes of a metal ion ' M^(3+) ' with three monodentate ligands L_(1),L_(2) and L_(3) absorb wavelengths in the region of green, blue and red respectively. The increasing order of the ligand strength is :

The maximum number of electrons that can be accomoddated in d_(x^(2)-y^(2)) orbital is

The maximum number of electrons that can be accomoddated in d_(x^(2)-y^(2)) orbital is

For the square planar complex [M(a) (b) (c ) (d)] (where M = central metal and a, b, c and d are monodentate ligands), the number of possible geometrical isomers are

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 .

An aqueous solution of metal ion MI reacts separately with reagents Q and R in excess to give tetrahedral and square planar complexes, respectively An aqueous solution of another metal ion M2 always forms tetrahedral complexs with theses reagents. Aqueous solution of M2 on reaction with reagent S gives white precipitate which dissolves in excess of S The reactions are summarised in the scheme given below: SCHEME : What is M2

A spinal is an important class of oxides consisting of two types of metal ions with oxides ions arranged in CCP layer. The normal spinal has one-eighth of the tetrahedral holes occupied by one type of metal ion and one-half of the octahedral holes occupied by another type of metal ion. such a spinal is formed by Zn^(2+), Al^(3+) and O^(2-) in the tetrahedral holes. if formula of the compound is Zn_(x)Al_(y) O_(z) , then find the value of (x + y + z) ?