Why is pyrene more reactive than benzene?

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Why is pyrene more reactive than benzene?

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Answer 1 · 2017-07-04T19:03:21

I would think that it's because pyrene has less resonance stabilization than benzene does (increasing its HOMO-LUMO gap by less), due to its sheer size causing its energy levels to be so close together.

A smaller HOMO-LUMO gap means a more reactive system, despite it having resonance throughout.

DISCLAIMER: THOROUGH/LONG ANSWER!

EXAMINING THE EXTENSIVITY OF RESONANCE STABILIZATION

Consider napthalene, anthracene, and phenanthrene (if you add one benzene ring to the upper-right of phenanthrene, you have pyrene):

![ www2.chemistry.msu.edu )

The resonance stabilization that one benzene ring gets is $36 kcal/mol$ $"36 kcal/mol"$ . If there were a perfect extensivity with regards to resonance stabilization, we would have expected the amount to be

$Total Resonance Energy$ $"Total Resonance Energy"$

$\approx Number of Benzene Rings \times Resonance Energy$ $~~ "Number of Benzene Rings" xx "Resonance Energy"$

But you can see in the above diagram that it isn't:

Napthalene has $11 kcal/mol$ $bb"11 kcal/mol"$ less resonance energy than $2 \times benzene rings$ $2xx"benzene rings"$ .
Anthracene has $25 kcal/mol$ $bb"25 kcal/mol"$ less resonance energy than $3 \times benzene rings$ $3xx"benzene rings"$ .
Phenanthrene has $17 kcal/mol$ $bb"17 kcal/mol"$ less resonance energy than $3 \times benzene rings$ $3xx"benzene rings"$ .

From this, we could postulate that in general, the more extended the $π$ $pi$ system, the less resonance stabilization is afforded. The most likely reason for this is probably the volume of the system.

ENERGY GAPS AS A FUNCTION OF VOLUME (AND ENTROPY)

The energy gaps (and thus the HOMO-LUMO gap) in any molecule are a function of the system volume and entropy.

At constant entropy though (which means at a constant distribution of states amongst the energy levels), the trend of volume vs. energy gap can be examined.

To illustrate this, the following graph was generated and derived from Huckel MO Theory, for which we have:

$E_{k} = α + 2 β cos (\frac{2 k π}{n})$ $E_k = alpha + 2betacos((2kpi)/n)$ ,

where $k$ $k$ is the energy level index and $n$ $n$ is the number of fused rings. $α$ $alpha$ is the nonbonding energy and $β$ $beta$ is the negative difference in energy from the nonbonding level.

We can see then that the HOMO-LUMO gap converges as the number of rings increases, i.e. as the system volume increases.

PARTICIPATION OF HOMO & LUMO IN ELECTROPHILIC ADDITION

How is this relevant?

Well, the HOMO and LUMO are both required in electrophilic addition reactions. For example, with adding ${Br}_{2}$ $"Br"_2$ ,

The HOMO donates $π$ $pi$ electrons to polarize ${Br}_{2}$ $"Br"_2$ and break the $Br - Br$ $"Br"-"Br"$ bond.
The LUMO accepts electrons from the $δ^{+} Br$ $stackrel(delta^(+))("Br")$ .

And this forms the so-called bromonium complex:

(Here, the HOMO contained the $π$ $pi$ electrons in the double bond, and the LUMO accepted the electrons from the bottom $Br$ $"Br"$ .)

Since the HOMO-LUMO gap gets smaller when the system gets larger, it's very likely that the gap is so small for pyrene that the resonance stabilization (which increases this gap) isn't enough to make it unreactive towards electrophilic addition.

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Why is pyrene more reactive than benzene?

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