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Ch. 12 - Substitution and Elimination: Reactions of Haloalkanes
Mullins - Organic Chemistry: A Learner Centered Approach 1st Edition
Mullins1st EditionOrganic Chemistry: A Learner Centered ApproachISBN: 9780137566471Not the one you use?Change textbook
All textbooksMullins 1st EditionCh. 12 - Substitution and Elimination: Reactions of HaloalkanesProblem 71
Chapter 11, Problem 71

Which is a better leaving group, HO⁻ or H2O? Explain your answer.
Comparison of HO⁻ and H₂O as leaving groups in substitution reactions, showing reaction pathways and products.

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Step 1: Understand the concept of a leaving group. A leaving group is an atom or group of atoms that can detach from the parent molecule during a chemical reaction, typically in substitution or elimination reactions. A good leaving group is stable after it leaves, often as a neutral molecule or a weak base.
Step 2: Compare the stability of HO⁻ (hydroxide ion) and H₂O (water) after they leave. HO⁻ is a negatively charged ion, while H₂O is a neutral molecule. Neutral molecules are generally more stable than charged species, making H₂O more stable than HO⁻.
Step 3: Consider the basicity of the leaving groups. HO⁻ is a strong base, meaning it is less stable and more reactive. H₂O, on the other hand, is a weak base and more stable. Weak bases tend to be better leaving groups because they are less likely to react after leaving.
Step 4: Evaluate the role of solvation and stabilization. In a polar solvent, H₂O can be further stabilized due to hydrogen bonding and dipole interactions, whereas HO⁻, being charged, may experience less stabilization compared to the neutral H₂O.
Step 5: Conclude that H₂O is a better leaving group than HO⁻ because it is neutral, more stable, and less basic, making it more favorable for detachment in a chemical reaction.

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Key Concepts

Here are the essential concepts you must grasp in order to answer the question correctly.

Leaving Groups

Leaving groups are atoms or groups of atoms that can depart from a molecule during a chemical reaction, typically in nucleophilic substitution or elimination reactions. A good leaving group is one that can stabilize the negative charge or is able to exist stably in solution after leaving. The ability of a leaving group to depart is influenced by its bond strength and the stability of the resulting species.
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Basicity and Leaving Group Ability

The basicity of a leaving group is inversely related to its ability to leave. Strong bases, like HO⁻ (hydroxide ion), are poor leaving groups because they are unstable and highly reactive in solution. In contrast, weaker bases, such as H₂O (water), are better leaving groups because they can stabilize the negative charge more effectively after departure, making them more favorable in substitution reactions.
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Stability of Leaving Groups

The stability of a leaving group after it departs is crucial in determining its effectiveness. Water (H₂O) is a stable molecule that can exist freely in solution, while hydroxide (HO⁻) is a highly reactive ion. The stability of the leaving group influences the reaction's kinetics and thermodynamics, with more stable leaving groups facilitating faster and more favorable reactions.
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Related Practice
Textbook Question

When trans-4-bromocyclohexanol is treated with base, an intramolecular substitution reaction occurs to give a cyclic ether. This product does not form when cis-4-bromocyclohexanol is reacted under the same conditions. Explain these observations.

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Textbook Question

Suggest a mechanism for the following reactions.

(b) Substitution :

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Textbook Question

Suggest a mechanism for the following reactions.

(a) Substitution:

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Textbook Question

The following chlorocyclohexane undergoes neither Sₙ2 nor E2 under the conditions shown. Why?

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Textbook Question

The following substitution reaction, between a strong base and a 1° haloalkane, occurs in a single step via backside displacement. Yet it is not technically an SN2 reaction. Why?

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Textbook Question

Using pKₐ values, calculate Keq for the following acid–base reaction.

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