Valence bond theory explains the geometry and magnetic nature of the coordination compounds .

On the basis of valence bond theory, explain the shape and magnetic behaviour of the following coordination compound : [Ni(CO)_4]

Using valence bond theory of complexes explain the geometry and diamagnetic nature of the ion, [Co(NH_3)_6]^(3+) .

Using valence bond theory explain the geometry and magnetic behaviour of pentacarbonyl iron (0).

Using valence bond theory , explain the geometry and magnetic behaviour of pentacarbonyl irom (0).

Using valence bond theory of complexes, explain the geometry and diamagnetic nature of the ion [Cr(NH_3)_6]^(3+) . Given the atomic number of Cr=24 .

Using valence bond theory of complexes, explain the geometry and diamagnetic nature of the ion [Cr(NH_3)_6]^(3+) . Given the atomic number of Cr=24 .

Using valence bond theory of complexes, explain the geometry and diamagnetic nature of the ion [Cr(NH_3)_6]^(3+) . Given the atomic number of Cr = 241.

Give an account of the valence bond theory . Explain the geometry and magnetic behaviour of the complex ion [Fe(CN)_(6)]^(4-) on the basis of the theory .

Write the main postulates of valence bond theory and explain the geometry and magnetic character (paramagnetism or diamagnetism) in the [FeF_6]^(3-) .

Write the main postulates of valence bond theory and explain the geometry and magnetic character (paramagnetism or diamagnetism) in the Ni(CO)_4