Question:

The ions $ {{N}^{3-}},{{O}^{2-}},{{F}^{-}},N{{a}^{+}}M{{g}^{2+}} $ are isoelectronic. Their ionic radii show

Updated On: Jun 23, 2023
  • an increase from $ {{N}^{3-}} $ to $ {{F}^{-}} $ and then decrease from $ N{{a}^{+}} $ to $ M{{g}^{2+}} $
  • a decrease from $ {{N}^{3-}} $ to $ {{F}^{-}} $ and then increase from $ N{{a}^{+}} $ to $ M{{g}^{2+}} $
  • a significant increase from $ {{N}^{3-}} $ to $ M{{g}^{2+}} $
  • a significant decrease from $ {{N}^{3-}} $ to $ M{{g}^{2+}} $
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The Correct Option is D

Solution and Explanation

Ionic radii
$ \propto \frac{1}{effective\text{ }nuclear\text{ }ch\arg e({{Z}_{eff}})} $
$ \propto negative\text{ }charge $
$ \propto \frac{1}{positive\text{ }charge} $
Hence, as the negative charge increases, ionic radii increases and with increase in positive charge ionic radii decrease. Hence, ionic radii decreases from
$ {{N}^{3-}} $ to $ M{{g}^{2+}} $
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Concepts Used:

Molecular Orbital Theory

The Molecular Orbital Theory is a more sophisticated model of chemical bonding where new molecular orbitals are generated using a mathematical process called Linear Combination of Atomic Orbitals (LCAO).

Molecular Orbital theory is a chemical bonding theory that states that individual atoms combine together to form molecular orbitals. Due to this arrangement in MOT Theory, electrons associated with different nuclei can be found in different atomic orbitals. In molecular orbital theory, the electrons present in a molecule are not assigned to individual chemical bonds between the atoms. Rather, they are treated as moving under the influence of the atomic nuclei in the entire molecule

Molecular Orbital Theory
Molecular Orbital Theory