The total spin resulting from a `d^7` configuration is :

The total spin resulting from d^(9) configuration is

Which has D configuration.

The colour in yisin results from the

Predict total spin for each configuration : (A) 1s^(2) " " (B) 1s^(2),2s^(2),2p^(6) (C ) 1s^(2),2s^(2),2p^(5) " " (D) 1s^(2),2s^(2),2p^(3) (E) 1s^(2),2s^(2)2p^(6),3s^(2) 3p^(6)3d^(5),4s^(2)

CFSE(Delta_(0)) for metal ion in d^7 configuration in presence of strong ligand field is

The element which does not show d^(@) configuration in its highest oxidation state

Colour blindness results from

Crystal field stabilization energy of high spin complex cation having d_5 configuration in an octahedral field is

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) .

For a d^4 metal ion in an octahedral field, the correct electronic configuration is :