(A): [Fe(edta)] complex is octahedral in shape
(R): edta ligand is hexadentate and forms six bonds with the metal atom undergoing `d^2sp^3` hybridization

Assertion: Ni(CO)_4 complex is tetrahedral in shape Reason: Ni atom undergoes sp^3 hybridization in Ni(CO)_4 .

(A) XeF_2 is a linear molecule (R) In XeF_2 xenon undergoes sp^3d hybridization

Which have octahedral shape (d^(2)sp^(3)) hybridisation of central atom :

(A): Central atom usually forms three single and one double bonds in an oxyacid of phosphorus (R): Phosphorus atom usually undergoes sp^(3) hybridisation in its oxyacids

Diborane is simplest and most familiar hydride of boton. Its chemical formula is B_(2)H_(6) . Comparing with ethane, diborane is regarded as electron deficient molecule. In the excited state boron of diborane undergoes sp^(3) hybridisation. Bonding in doborane is described as tricentric two electron bonding. Number of empty sp^(3) hybrid orbitals of each ''B'' atom in B_(2)H_(6) Each B contains one sp^(3) vacant hybrid orbital

The d-orbitals participating in hybridisation of metal atom may be from the n & (n-1) shell. This depends on the nature of metal and nature of ligand. The complexes involving the inner d-level (inner orbital complexes) results when the ligand is a powerful (or) strong ligand results in a diamagnetic (or) low spin complexes. A weak ligand usually results in the formation of outer orbital complex (or) high spin complex. The hybridisation of Cu in [CuCl_(4)]^(2-)&[Cu(NH_(3))_(4)]^(2+) are respectivly

Assertion: The number of unpaired electrons in Ni(CO)_4 complex is zero. Reason : 4s electrons of Ni atom enter the inner d-orbitals to facilitate the sp^3 hybridization in Ni atom.

Complex compounds are molecular compounds which retain their indentities 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 struculre, magnetic property, colour and electrical properties of complexes are explained by various theories. Arrange the following compounds in order of of their molar conductance : i) K[Co(NO_(2))_(4)(NH_(3))_(2)] ii) [Cr(ONO)_(3)(NH_(3))_(3)] iii) [Cr(NO_(2))(NH_(3))_(5)]_(3)[Co(NO_(2))_(6)]_(2) iv) Mg[Cr(NO_(2))_(5)(NH_(3))]