The Fascinating Hexanitrocuprate (II) Ion: Unveiling its Distorted Octahedral Structure

Why does the hexanitrocuprate (II) ion adopt a distorted octahedral structure?

Is there a difference in bond lengths between the axial and planar ligands in the hexanitrocuprate (II) ion?

Answer:

In the hexanitrocuprate (II) ion, the axial ligands have a longer bond length than the planar ligands because of the Jahn-Teller distortion which is caused by repulsions between electron orbitals.

The hexanitrocuprate (II) ion, with the chemical formula [Cu(NO2)6]4-, showcases a fascinating distorted octahedral structure. This distortion arises from the repulsions between electron orbitals, leading to a unique bond length difference between the axial and planar ligands.

As mentioned earlier, the axial ligands in hexanitrocuprate (II) ion have a bond length of 2.313 Angstroms, while the planar ligands have a bond length of 2.050 Angstroms. This variance in bond lengths is a direct result of the Jahn-Teller distortion phenomenon.

The Jahn-Teller effect occurs in coordination compounds with a d9 configuration, such as the Cu2+ ion in hexanitrocuprate (II) ion. This effect causes the distortion in the octahedral structure due to the repulsions between adjacent nitro groups' oxygen atoms. The axial ligands, situated along the z-axis, are more influenced by the electronegative oxygen atoms of the equatorial ligands, leading to their slightly longer bond length compared to the planar ligands.

Understanding the intricacies of the Jahn-Teller distortion sheds light on the structural uniqueness of the hexanitrocuprate (II) ion and its distorted octahedral configuration.

← Is calcium carbide ionic or covalent compound Calculate molecular weight of a gas →