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Chapter 14: Problem 45

Explain why the substitution reactions of the following halonaphthalenes give about the same ratio of 1 - and 2- naphthyl products independently of the halogen substituent and the nucleophilic reagent. Show the steps involved.

Short Answer

Expert verified
The reaction favors the 1 and 2 positions due to similar resonance stabilization opportunities, unaffected by halogen or nucleophile choice.

Step by step solution

01

Understand the structure of naphthalene

Naphthalene consists of two fused aromatic rings. In these rings, the positions can be numbered to identify where substitution occurs. The positions 1 and 2 are adjacent to each other on the ring, making them the most likely sites for substitution reactions.
02

Analyze resonance stabilization

When a substituent is added to naphthalene, it can stabilize itself through resonance structures. Positions 1 and 2 provide similar opportunities for resonance stabilization, due to the structure of the naphthalene ring.
03

Consider halogen effects

Halogens are ortho-para directing due to their ability to participate in resonance, which means they favor substitution at the 1 and 2 positions to maximize resonance stabilization. This property is largely independent of the type of halogen used, whether it be fluorine, chlorine, bromine, or iodine.
04

Evaluate nucleophile effects

Nucleophiles also influence the reaction but similarly affect the 1 and 2 positions due to the uniform chance for resonance stabilization. Consequently, whether the nucleophile is strong or weak doesn't significantly change the proportion of substitution at these positions.
05

Conclude why the reactivity is uniform

Given the resonance stabilization opportunity at both positions and the consistent directing effect of halogens and nucleophiles, the reaction naturally favors substitution at positions 1 and 2 without significant variation, regardless of the specific halogen or nucleophile involved.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Halonaphthalenes
Halonaphthalenes are compounds formed by the substitution of halogen atoms like chlorine, bromine, or iodine into the naphthalene structure. Naphthalene, known for its distinct aromaticity, consists of two fused benzene rings.
Naphthalenes can have their halogen substituents positioned at different sites, numbered as 1-naphthyl and 2-naphthyl positions.
This numbering is crucial as it determines the site of chemical reactions. Halonaphthalenes are interesting in substitution reactions because they involve interactions between the aromatic rings and the halogen atoms. The chemical behavior observed — independent of the halogen type — is due to the unified structure of the naphthalene. This aromatic system allows consistent approaches for substitution reactions.
Resonance Stabilization
Resonance stabilization in chemistry refers to the ability of a molecule to delocalize electrons across different structures, which adds stability. In naphthalene, resonance stabilization plays a significant role, especially when substitution occurs at the 1 and 2 positions.
These positions allow the electrons and charge to be resonated through the aromatic rings seamlessly.
  • Enhanced stability is achieved because resonance structures share electrons over a larger volume.
  • This helps maintain the aromatic nature of naphthalene, even after substitution.
Hence, both the 1 and 2 positions show similar likelihoods for stabilization, explaining their consistent reactivity positions in substitution reactions.
Nucleophilic Reagent
Nucleophilic reagents are species that donate an electron pair to an electrophile to form new chemical bonds during a reaction. They are vital components in substitution reactions of halonaphthalenes.
Despite variations in strength or stability among different nucleophiles, their influence on 1- and 2-naphthyl positions is remarkably consistent. This consistency is because both positions offer similar electronic environments for the participating nucleophiles.
Resonance plays a crucial part here, as it mitigates differences, allowing similar reactivity for various nucleophiles. Moreover, nucleophiles tend to target sites where electron deficiency is mirrored by resonance stabilization, thus slightly favoring these particular reaction sites.
Halogen Substituent
Halogen substituents such as fluorine, chlorine, bromine, and iodine can direct substitution reactions, further influencing the chemistry of halonaphthalenes. Despite their differences in size, electronegativity, and bond formation capacity, their overall effect on substitution positions remains invariant.
  • Halogens can act as ortho-para directors in aromatic systems due to their resonance ability.
  • This results in preference for substitutions at the 1- and 2- positions, which provide optimal stabilization.
Ultimately, this position preference is due to their capability to engage in resonance. This stabilizes any potential charged intermediates that might form during the chemical reaction. Thus, regardless of which halogen is present, the reaction outcomes in terms of positional substitution exhibit high uniformity.

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Most popular questions from this chapter

The rate of addition of dimethylmagnesium to excess diphenylmethanone (benzophenone) in diethyl ether initially is cleanly second order, that is, first order in ketone and first order in \(\left(\mathrm{CH}_{3}\right)_{2} \mathrm{Mg}\). As the reaction proceeds, the rate no longer follows a strictly second-order rate overall. Suggest how the apparent specific rate could change as the reaction proceeds.

In the presence of only traces of ionizing agents, either pure 1 -chloro-2-butene or 3 -chloro-1-butene is converted slowly to a 50-50 equilibrium mixture of the two chlorides. Explain.

The reactions of several 1-substituted 2,4-dinitrobenzenes with piperidine (azacyclohexane), Equation \(14-5\), proceed at nearly the same rate, independent of the nature of \(\mathrm{X}\). Rationalize this observation in terms of a mechanism of nucleophilic aromatic substitution.

Compound X, of formula \(\mathrm{C}_{3} \mathrm{H}_{5} \mathrm{Br}_{3}\), with methyllithium formed bromocyclopropane and 3-bromopropene. The NMR spectrum of \(\mathrm{X}\) showed a one-proton triplet at \(5.9 \mathrm{ppm}\), a two-proton triplet at \(3.55 \mathrm{ppm}\), and a complex resonance centered at \(2.5\) ppm downfield from TMS. What is the structure of \(X\) ? Account for the products observed in its reaction with methyllithium.

The following experimental observations have been reported: 1\. tert-Butyl chloride was added to lithium metal in dry ether at \(35^{\circ}\). A vigorous reaction ensued with evolution of hydrocarbon gases. After all the lithium metal was consumed, the mixture was poured onto dry ice. The only acidic product that could be isolated (small yield) was 4,4-dimethylpentanoic acid. 2\. tert-Butyl chloride was added to lithium metal in dry ether at \(-40^{\circ}\). After all the lithium had reacted, the mixture was carbonated and gave a good yield of 2,2-dimethylpropanoic acid. 3\. tert-Butyl chloride was added to lithium metal in dry ether at \(-40^{\circ} .\) After all the lithium was consumed, ethene was bubbled through the mixture at \(-40^{\circ}\) until no further reaction occurred. Carbonation of this mixture gave a good yield of 4,4-dimethylpentanoic acid. a. Give a reasonably detailed analysis of the results obtained and show as best you can the mechanisms involved in each reaction. b. Would similar behavior be expected with methyl chloride? Explain. c. Would you expect that a substantial amount of 6,6-dimethylheptanoic acid would be found in Observation 3? Explain.
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