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

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

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 .

Using valence bond theory predict the geometry and magnetic behaviour of [Pt(CN)_4]^(2-) .

Using valence bond theory, predict the geometry and magnetic behaviour of [Cr(NH_3)_6]^(+) ion.

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

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.