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Question
Magnesium loses electrons successively to form Mg+, Mg2+ and Mg3+ ions. Which step will have the highest ionisation energy and why?
Solution
\[\ce{\underset{\text{Neutral atom}}{Mg_{(g)}} -> Mg^+ + e}\] (I.E1 = X1) (Deb: e or e−)
\[\ce{\underset{\text{Unipositive cation}}{Mg^+} -> Mg^2+ + e^-}\] (I.E2 = X2)
\[\ce{\underset{\text{Dipositive cation}}{Mg^2+} -> Mg^3+ + e^-}\] (I.E3 = X3)
- The third step will have the highest ionization energy. I.E3 > I.E2 > I.E1
- Because from a neutral gaseous atom, the electron removal is easy and less amount of energy is required. But from a di positive cation, there will be more protons than the electrons and there are more forces of attraction between the nucleus and electron. So the removal of electrons in a di positive cation becomes highly difficult and more energy is required.
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