On the basis of crystal field theory,explain why $Co(III)$ forms a paramagnetic octahedral complex with weak field ligands,whereas it forms a diamagnetic octahedral complex with strong field ligands.
(N/A) $Co^{3+}$ has a $d^{6}$ electronic configuration.
In the presence of a strong field ligand,the crystal field splitting energy $\Delta_{o}$ is greater than the pairing energy $P$ (i.e.,$\Delta_{o} > P$). This forces the electrons to pair up in the lower energy $t_{2g}$ orbitals,resulting in a $t_{2g}^{6} e_{g}^{0}$ configuration.
Since all electrons are paired in the $t_{2g}^{6} e_{g}^{0}$ configuration,the complex is diamagnetic.
In the presence of a weak field ligand,$\Delta_{o} < P$. The electrons occupy the higher energy $e_{g}$ orbitals before pairing occurs,resulting in a $t_{2g}^{4} e_{g}^{2}$ configuration.
In the $t_{2g}^{4} e_{g}^{2}$ configuration,there are four unpaired electrons,making the complex paramagnetic.
In the presence of a strong field ligand,the crystal field splitting energy $\Delta_{o}$ is greater than the pairing energy $P$ (i.e.,$\Delta_{o} > P$). This forces the electrons to pair up in the lower energy $t_{2g}$ orbitals,resulting in a $t_{2g}^{6} e_{g}^{0}$ configuration.
Since all electrons are paired in the $t_{2g}^{6} e_{g}^{0}$ configuration,the complex is diamagnetic.
In the presence of a weak field ligand,$\Delta_{o} < P$. The electrons occupy the higher energy $e_{g}$ orbitals before pairing occurs,resulting in a $t_{2g}^{4} e_{g}^{2}$ configuration.
In the $t_{2g}^{4} e_{g}^{2}$ configuration,there are four unpaired electrons,making the complex paramagnetic.
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Similar Questions
The complex that has the highest crystal field splitting energy $(\Delta)$ is
$A$ $[M(H_2O)_6]^{2+}$ complex typically absorbs at around $600 \ nm$. It is allowed to react with ammonia to form a new complex $[M(NH_3)_6]^{2+}$ that should have absorption at ....... $nm$.
Match List-$I$ with List-$II$:
List-$I$ (Complex) List-$II$ ($CFSE$ in $\Delta_0$) $A$. $[Cu(NH_3)_6]^{2+}$ $I$. $-0.6$ $B$. $[Ti(H_2O)_6]^{3+}$ $II$. $-2.0$ $C$. $[Fe(CN)_6]^{3-}$ $III$. $-1.2$ $D$. $[NiF_6]^{4-}$ $IV$. $-0.4$
Choose the correct answer from the options given below:
| List-$I$ (Complex) | List-$II$ ($CFSE$ in $\Delta_0$) |
|---|---|
| $A$. $[Cu(NH_3)_6]^{2+}$ | $I$. $-0.6$ |
| $B$. $[Ti(H_2O)_6]^{3+}$ | $II$. $-2.0$ |
| $C$. $[Fe(CN)_6]^{3-}$ | $III$. $-1.2$ |
| $D$. $[NiF_6]^{4-}$ | $IV$. $-0.4$ |
Choose the correct answer from the options given below:
Why are low spin tetrahedral complexes not formed?
Which of the following is the correct order of crystal field splitting strength for ligands based on the donor atom?
Medium
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