Let’s consider
the following carbocations and rank them in terms of their stability:
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Fig. 1: Carbocation 1 is stabilized by the –OCH3 substituent
since it is electron donating. The + charge is delocalized and the
carbocation is stabilized. Carbocation 2 is destabilized by the electron
withdrawing substituent NO2. By drawing the resonance structure we
see that there are two adjacent positive charges. This resonance structure is
highly unfavorable!
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The substituent (-OCH3) stabilizes carbocation 1 by resonance
and the resulting charge delocalization. The + charge is delocalized to the O
atom.
The substituent (-NO2+) in carbocation 2 is
electron-withdrawing and the carbocation is destabilized. Notice the two
adjacent + charges.
In general, carbocations are destabilized by neighboring
electron-withdrawing groups if:
- Contain an atom more electronegative than C
- There is no atom with an electron pair that is directly attached to the carbocation (-CF3, -CCl3, -C(O)R, -+NR3, -CN, -NO2, -C(O)-OH, -S(O)2OH)
For example let
us consider the following carbocations and rank them in terms of stability:
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Fig. 2: The carbocation with the CH3
substituent is more stable than the carbocation with the electron-withdrawing
CF3 substituent.
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The carbocation
with the CH3 group in Figure 1 is more stable than the carbocation
with the -CF3 group. Notice the partial + charge (d+) on the carbon
atom due to the electron withdrawing effect of the fluorine atoms. The
carbocation is destabilized due to the adjacent positive charge and partial
positive charge.
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