chevron_left Tertiary halogenoalkanes feature a halogen on a carbon bonded to three alkyl groups chevron_right

Anna Kowalski

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calendar_month2025-11-29

Tertiary Halogenoalkanes: A Complete Guide

Understanding the structure, properties, and reactions of carbon compounds where a halogen is attached to a carbon bonded to three other carbons.

Summary: A tertiary halogenoalkane is a specific type of organic molecule where a halogen atom, such as chlorine or bromine, is bonded to a carbon atom that is itself connected to three other carbon atoms. This unique molecular structure is the key to understanding its distinct chemical behavior, including its high reactivity in substitution and elimination reactions. This article will explore how to identify these compounds, how they are made, and why their structure leads to their characteristic reaction mechanisms, making them a fundamental topic in organic chemistry.

What is a Tertiary Halogenoalkane?

To understand a tertiary halogenoalkane, we first need to break down the name. A halogenoalkane (also called an alkyl halide) is an organic compound containing one or more halogen atoms (fluorine, chlorine, bromine, or iodine) bonded to a carbon atom in an alkane chain. The "tertiary" part describes the level of the carbon atom that holds the halogen.

Carbon atoms can be classified based on the number of other carbon atoms they are directly attached to:

Primary (1°) carbon: Bonded to 1 other carbon.
Secondary (2°) carbon: Bonded to 2 other carbons.
Tertiary (3°) carbon: Bonded to 3 other carbons.

Therefore, a tertiary halogenoalkane has the general structure shown below, where the "R" groups represent alkyl groups (which are fragments of alkanes like -CH₃, -C₂H₅, etc.).

General Formula: $ R_1R_2R_3C-X $
Where $ X $ is a halogen ($ F, Cl, Br, I $) and $ R_1 $, $ R_2 $, and $ R_3 $ are alkyl groups, which can be the same or different.

A classic example is 2-bromo-2-methylpropane, formerly known as tert-butyl bromide. Its structure is $(CH_3)_3CBr$. The central carbon is bonded to three methyl groups ($-CH_3$) and one bromine atom, making it a perfect model of a tertiary halogenoalkane.

Naming and Identifying Tertiary Halogenoalkanes

Following IUPAC^[1] naming rules is the best way to identify the class of a halogenoalkane. The number in the name often reveals the carbon's status.

Let's look at some examples with four-carbon chains:

Name	Structural Formula	Carbon Type	Explanation
1-bromobutane	$ CH_3CH_2CH_2CH_2Br $	Primary	The Br is on a carbon bonded to only 1 other carbon.
2-bromobutane	$ CH_3CH_2CHBrCH_3 $	Secondary	The Br is on a carbon bonded to 2 other carbons.
2-bromo-2-methylpropane	$(CH_3)_3CBr$	Tertiary	The Br is on a carbon bonded to 3 other carbons.

As you can see, the carbon holding the halogen in 2-bromo-2-methylpropane is a tertiary carbon, making the entire molecule a tertiary halogenoalkane.

How Tertiary Halogenoalkanes are Made

Tertiary halogenoalkanes can be produced through several methods. The most common one is the free radical substitution reaction of an alkane with a halogen. However, this method often gives a mixture of products. A more targeted approach is the addition of a hydrogen halide to an alkene.

Addition of HBr to an Alkene (Markovnikov's Rule): When an unsymmetrical alkene like propene reacts with HBr, the hydrogen atom attaches to the carbon of the double bond that already has more hydrogen atoms. The halogen ends up on the more substituted carbon, which can often result in a tertiary halogenoalkane if the alkene is branched.

Example Reaction:
Addition to 2-methylpropene: $ (CH_3)_2C=CH_2 + HBr \rightarrow (CH_3)_3CBr $
Here, 2-methylpropene reacts with hydrogen bromide to form the tertiary halogenoalkane 2-bromo-2-methylpropane.

Chemical Reactions: Why Structure Matters

The "tertiary" structure has a profound impact on how these molecules react. The carbon-halogen bond in a tertiary halogenoalkane is relatively weak because the three alkyl groups crowd the central carbon, making it easier for the bond to break. This is an example of steric hindrance^[2] actually increasing reactivity in certain mechanisms.

The two most important reaction types for halogenoalkanes are nucleophilic substitution and elimination.

Nucleophilic Substitution Reactions

In this reaction, a nucleophile^[3] (a species that loves positive charges) attacks the electron-deficient carbon attached to the halogen, replacing the halogen atom. Tertiary halogenoalkanes primarily undergo an $ S_N1 $ mechanism.

The $ S_N1 $ Mechanism (Substitution, Nucleophilic, Unimolecular):

Step 1 (Slow): The carbon-halogen bond breaks to form a stable carbocation^[4] intermediate. Tertiary carbocations are very stable because the three alkyl groups donate electron density to the positive carbon.
Step 2 (Fast): The nucleophile rapidly attacks the carbocation to form the final substitution product.

For example, the hydrolysis of 2-bromo-2-methylpropane with aqueous sodium hydroxide is slow but follows the $ S_N1 $ path, producing 2-methylpropan-2-ol.

$ S_N1 $ Reaction Example:
$ (CH_3)_3CBr + OH^- \rightarrow (CH_3)_3COH + Br^- $
(2-bromo-2-methylpropane + hydroxide ion → 2-methylpropan-2-ol + bromide ion)

Elimination Reactions

Under strong basic conditions (like hot ethanolic KOH), tertiary halogenoalkanes readily undergo elimination to form alkenes. In this reaction, a base removes a hydrogen atom from a carbon adjacent to the C-X carbon, leading to the loss of HX and the formation of a double bond. They favor the $ E1 $ mechanism, which also involves a carbocation intermediate.

Elimination Reaction Example:
$ (CH_3)_3CBr + OH^- \ (hot, ethanolic) \rightarrow (CH_3)_2C=CH_2 + H_2O + Br^- $
(2-bromo-2-methylpropane → 2-methylpropene)

Comparing Reactivity: Primary vs. Tertiary

The reactivity of halogenoalkanes depends heavily on their structure and the reaction mechanism. The table below provides a simplified comparison.

Property / Reaction	Primary Halogenoalkane	Tertiary Halogenoalkane
Example	1-bromobutane ($ CH_3CH_2CH_2CH_2Br $)	2-bromo-2-methylpropane ($ (CH_3)_3CBr $)
Strength of C-X bond	Stronger	Weaker
Favored Substitution Mechanism	$ S_N2 $	$ S_N1 $
Rate of Hydrolysis with $ OH^- $	Slower (for $ S_N2 $)	Faster (due to $ S_N1 $)
Favored Reaction with Strong Base	Substitution ($ S_N2 $)	Elimination ($ E1 $)

A Practical Example: From Starting Material to Product

Let's follow a real-world scenario involving a tertiary halogenoalkane. Imagine a chemist wants to synthesize the alkene 2-methylpropene, a useful compound in making plastics and fuels.

Step 1: Make the Tertiary Halogenoalkane. The chemist starts with 2-methylpropene, which might seem odd, but this is a common lab preparation. They react the alkene with hydrogen bromide (HBr). Following Markovnikov's rule, the H and Br add across the double bond to form the stable tertiary halogenoalkane, 2-bromo-2-methylpropane.
Step 2: Convert it Back to the Alkene. Now, to get a purer sample of the original alkene, the chemist treats the 2-bromo-2-methylpropane with a hot, concentrated solution of potassium hydroxide in ethanol. This strong base promotes an elimination reaction ($ E1 $), removing HBr and regenerating 2-methylpropene.

This cycle demonstrates the interconversion between alkenes and halogenoalkanes and highlights the utility of tertiary halogenoalkanes as intermediates in organic synthesis.

Important Questions

Q1: Why are tertiary halogenoalkanes more reactive than primary ones in nucleophilic substitution?

Their high reactivity is due to the stability of the tertiary carbocation intermediate formed in the $ S_N1 $ mechanism. The three alkyl groups around the positive carbon help to spread out and stabilize the positive charge, making it easier to form. This lowers the energy barrier for the rate-determining step (the first step where the C-X bond breaks), resulting in a faster reaction compared to primary halogenoalkanes, which have to use the slower $ S_N2 $ mechanism.

Q2: What is the main product when a tertiary halogenoalkane reacts with a strong base?

The main product is typically an alkene via an elimination reaction. While substitution is possible, elimination is heavily favored for tertiary halogenoalkanes under strong basic conditions, especially at higher temperatures. For example, 2-bromo-2-methylpropane with hot ethanolic KOH gives 2-methylpropene as the major product.

Q3: How can I quickly identify if a halogenoalkane is tertiary from its name?

Look at the number immediately before the part of the name that indicates the halogen's position. If that number is the same in two different parts of the name, or if it's a low number attached to multiple alkyl groups, it's a strong indicator. For instance, in 2-bromo-2-methylpropane, the number "2" appears twice, meaning both the bromine and a methyl group are on the same carbon. A carbon that has two substituents (other than H) is often secondary, but if it has three (like in this case: one Br and two methyl groups from the "2-methyl" and the base name "propane"), it is a tertiary carbon.

Conclusion: The journey into the world of tertiary halogenoalkanes reveals a core principle of organic chemistry: structure determines reactivity. The simple fact that the carbon-halogen bond is attached to three other carbon atoms dictates a unique set of chemical behaviors. This structure leads to weaker C-X bonds, a preference for the $ S_N1 $ and $ E1 $ reaction mechanisms involving stable carbocation intermediates, and generally faster reaction rates compared to their primary counterparts. From their synthesis via addition to alkenes to their role as key intermediates in creating other molecules like alcohols and alkenes, understanding tertiary halogenoalkanes provides a powerful tool for predicting and explaining the outcomes of countless chemical reactions.

Footnote

^[1] IUPAC: International Union of Pure and Applied Chemistry. This body establishes the standard rules for naming chemical compounds.
^[2] Steric Hindrance: The slowing of a chemical reaction due to the physical bulk of groups within a molecule. In tertiary halogenoalkanes, the bulky groups hinder the $ S_N2 $ mechanism but favor the $ S_N1 $ mechanism by stabilizing the carbocation.
^[3] Nucleophile: A chemical species that donates an electron pair to form a chemical bond. Examples include hydroxide ion ($ OH^- $), water ($ H_2O $), and ammonia ($ NH_3 $).
^[4] Carbocation: An ion with a positively charged carbon atom. The stability of carbocations follows the order: tertiary > secondary > primary > methyl.

#AS & A Level #Organic Chemistry #Nucleophilic Substitution #Carbocation #Elimination Reaction #SN1 Mechanism

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