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Question
A solution of \[\ce{[Ni(H2O)6]^2+}\] is green, whereas a solution of \[\ce{[Ni(CN)4]^2-}\] is colorless – Explain.
Solution
1. In \[\ce{[Ni(H2O)6]^2+}\], Ni is in +2 oxidation state with the configuration 3d8, i.e., it has two unpaired electrons which do not pair up in the presence of weak H2O ligand. Hence, it is coloured. The d – d transition absorbs red light and the complementary light emitted is green.
2. In the case of \[\ce{[Ni(CN)4]^2-}\], Ni is again in +2 oxidation state with the configuration 3d8, but in the presence of strong CN– ligand the two impaired electrons in the 3d orbitals pair up. Thus there is no unpaired electron present. Hence it is colourless. Therefore, a solution of \[\ce{[Ni(H2O)6]^2+}\] is green, whereas a solution of \[\ce{[Ni(CN)4]^2-}\] is colourless.
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