The magnetic moment is measured in Bohr Magneton (). Spin only magnetic moment of Fe in and complexes respectively is:
- A
B.M. and B.M.
- B
B.M. in both
- C
B.M. and B.M.
- D
B.M. and B.M.
The magnetic moment is measured in Bohr Magneton (). Spin only magnetic moment of Fe in and complexes respectively is:
B.M. and B.M.
B.M. in both
B.M. and B.M.
B.M. and B.M.
Correct answer:C
Standard Method
Given: The complexes are and .
Find: The spin only magnetic moments of Fe in both complexes.
For , the electronic configuration is .
In , is a weak field ligand, so no pairing occurs. Hence the number of unpaired electrons is .
The spin-only magnetic moment is
Substituting ,
In , is a strong field ligand, so pairing occurs. Hence the number of unpaired electrons is .
Again using
Substituting ,
Therefore, the spin-only magnetic moments are and respectively. The correct option is C.
Electron Configuration Explanation
Given: Both complexes contain .
Find: How ligand strength changes the number of unpaired electrons and hence the magnetic moment.
Neutral Fe has configuration . Removing three electrons gives
For , is a weak field ligand, so the complex is high spin. Thus all five electrons remain unpaired.
For , is a strong field ligand, so the complex is low spin. The electrons pair as much as possible, leaving only one unpaired electron.
Now apply
For the first complex, gives . For the second complex, gives .
Hence the correct choice is C. The solution says option A, but its worked values clearly match option C. Therefore the worked solution determines the answer.
Assuming both complexes have the same magnetic moment because Fe is in the oxidation state in both is incorrect. Ligand strength changes the number of unpaired electrons. Always determine whether the ligand is weak field or strong field before counting unpaired electrons.
Using the neutral Fe configuration instead of is wrong. First remove electrons to get , then analyze the crystal field splitting.
Treating as a strong field ligand or as a weak field ligand gives the wrong spin state. Remember that usually forms a high-spin complex, while usually forms a low-spin complex.
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