CHM-623›[1,7] Hydrogen Migration

Rearrangements and Pericyclic ReactionsTopic 19 of 31

[1,7] Hydrogen Migration

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Intermediatelevel

[1,7] Hydrogen Migration

The [1,7] hydrogen migration is a type of hydrogen shift where a hydrogen atom migrates over seven positions (or six intervening atoms) along a carbon chain or in a cyclic structure. This type of migration occurs in reactions that involve pericyclic mechanisms, radical intermediates, or sigmatropic rearrangements. The migration of a hydrogen atom from one carbon to another with a 1,7 shift plays a significant role in the formation of conjugated systems, ring formation, and other complex rearrangements.

Mechanism of [1,7] Hydrogen Migration

The [1,7] hydrogen migration involves the movement of a hydrogen atom from one atom to another, typically across a longer chain or conjugated system. In this type of migration, the hydrogen moves over a seven-atom span, which can be part of a broader rearrangement or reaction mechanism.

General Example

Consider the molecule oct-1,7-diene:

\text{CH₂=CH–CH₂–CH₂–CH₂–CH₂–CH₂} \xrightarrow{\text{[1,7] hydrogen migration}} \text{CH₃–CH₂–CH=CH–CH₂–CH₂–CH₂}

In this example, the hydrogen atom on carbon 2 migrates to carbon 7, resulting in the shift of the hydrogen and the repositioning of the double bond to form a more stable structure.

Types of Reactions Involving [1,7] Hydrogen Migration

Sigmatropic Rearrangements:
- The [1,7] hydrogen migration is typically part of a sigmatropic rearrangement. These are concerted reactions where bonds break and form simultaneously in a cyclic manner, involving hydrogen shifts over long distances (such as the [1,7] shift).
- In sigmatropic reactions, the hydrogen migration is often accompanied by other atom or group migrations. The reaction is concerted, meaning the atoms involved in the shift move simultaneously in a single transition state.
Pericyclic Reactions:
- In pericyclic reactions, [1,7] hydrogen shifts can occur in concerted transitions, typically involving π-electron systems (such as in dienes or cycloheptatriene derivatives) where the hydrogen atom migrates in a cyclic fashion during the rearrangement process. These are usually part of larger shifts involving other atoms or groups in the molecule.
Radical Mechanisms:
- Radical reactions may also involve [1,7] hydrogen migrations, where a radical center forms on one atom, and the hydrogen atom migrates over seven positions to stabilize the radical. This migration can result in the formation of a new bond or rearranged structure.

Example of a Radical Mechanism:

If a molecule with a radical at one end undergoes a [1,7] hydrogen migration, the hydrogen atom shifts over six atoms, potentially stabilizing the radical center. For instance:

\text{CH₃–CH₂–CH₂·} \xrightarrow{\text{[1,7] hydrogen migration}} \text{CH₂=CH–CH₂·}

Here, the radical on carbon 3 can migrate to carbon 7, stabilizing the molecule through the migration of a hydrogen atom.

Cyclization Reactions:
- The [1,7] hydrogen shift can also be involved in cyclization reactions where a hydrogen atom migrates across a long chain to form a new ring structure. The shift of the hydrogen atom can promote ring closure or form conjugated systems.

Examples of [1,7] Hydrogen Migration in Organic Chemistry

1. Cycloheptatriene Derivatives

In cycloheptatriene (C₇H₈) or similar heptatriene derivatives, [1,7] hydrogen migrations can be part of rearrangements leading to tropylium ions or other aromatic systems. The hydrogen shift is crucial for the stabilization of intermediate radicals or the formation of aromatic systems. The [1,7] hydrogen shift can be involved in the process of ring closure or formation of more stable products.

2. [1,7] Hydrogen Migration in Diene Systems

In systems such as dienes, where there are conjugated double bonds, [1,7] hydrogen migrations can lead to conjugation and ring closure:

\text{CH₂=CH–CH₂–CH₂–CH₂–CH₂–CH₂} \xrightarrow{\text{[1,7] hydrogen migration}} \text{CH₂=CH–CH₂–CH₂–CH=CH₂}

This rearrangement is important in organic synthesis, where such shifts can facilitate the formation of stable conjugated systems or intermediate structures that are useful in polymerization reactions or ring formation.

Stereochemistry of [1,7] Hydrogen Migration

The stereochemistry of [1,7] hydrogen migration depends on the specific reaction mechanism:

Concerted Mechanisms (e.g., in sigmatropic rearrangements): The migration typically occurs in a stereospecific manner. The transition state must involve the simultaneous movement of atoms, leading to a specific stereochemistry in the final product.
Radical Processes: In radical mechanisms, the migration may be non-stereoselective, leading to a mixture of stereoisomers. The radical intermediate can lead to different possible configurations of the final product, as the hydrogen atom may migrate in any direction along the chain.

Applications of [1,7] Hydrogen Migration

Synthesis of Complex Molecules:
- The [1,7] hydrogen migration plays a crucial role in the synthesis of complex organic molecules, including the formation of cyclic compounds and conjugated systems. These shifts enable the formation of stable intermediates and contribute to the functionalization of molecules.
Stabilization of Radicals:
- In radical chain processes, [1,7] hydrogen migrations help stabilize the radical intermediates, leading to more favorable reaction pathways and the formation of stable products.
Cyclization and Aromatization:
- The [1,7] hydrogen migration can be essential in cyclization reactions, facilitating ring closure or aromatization. These processes are important in the synthesis of aromatic compounds or heterocyclic structures.
Conjugated Systems:
- The migration of hydrogen atoms across long distances, such as the [1,7] shift, can help create or stabilize conjugated systems, which are valuable in organic electronic devices and photochemical reactions.

Conclusion

The [1,7] hydrogen migration is a crucial concept in organic chemistry, particularly in the context of sigmatropic rearrangements, pericyclic reactions, radical mechanisms, and cyclization reactions. The migration of a hydrogen atom over seven positions plays an important role in the formation of stable intermediates, conjugated systems, and ring structures. Understanding this migration allows chemists to design more efficient synthetic routes and better control over reaction mechanisms, making it an important tool in organic synthesis.

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CHM-623›[1,7] Hydrogen Migration

Rearrangements and Pericyclic ReactionsTopic 19 of 31

[1,7] Hydrogen Migration

6 minread

989words

Intermediatelevel

[1,7] Hydrogen Migration

Mechanism of [1,7] Hydrogen Migration

General Example

Consider the molecule oct-1,7-diene:

\text{CH₂=CH–CH₂–CH₂–CH₂–CH₂–CH₂} \xrightarrow{\text{[1,7] hydrogen migration}} \text{CH₃–CH₂–CH=CH–CH₂–CH₂–CH₂}

In this example, the hydrogen atom on carbon 2 migrates to carbon 7, resulting in the shift of the hydrogen and the repositioning of the double bond to form a more stable structure.

Types of Reactions Involving [1,7] Hydrogen Migration

Sigmatropic Rearrangements:
- The [1,7] hydrogen migration is typically part of a sigmatropic rearrangement. These are concerted reactions where bonds break and form simultaneously in a cyclic manner, involving hydrogen shifts over long distances (such as the [1,7] shift).
- In sigmatropic reactions, the hydrogen migration is often accompanied by other atom or group migrations. The reaction is concerted, meaning the atoms involved in the shift move simultaneously in a single transition state.
Pericyclic Reactions:
- In pericyclic reactions, [1,7] hydrogen shifts can occur in concerted transitions, typically involving π-electron systems (such as in dienes or cycloheptatriene derivatives) where the hydrogen atom migrates in a cyclic fashion during the rearrangement process. These are usually part of larger shifts involving other atoms or groups in the molecule.
Radical Mechanisms:
- Radical reactions may also involve [1,7] hydrogen migrations, where a radical center forms on one atom, and the hydrogen atom migrates over seven positions to stabilize the radical. This migration can result in the formation of a new bond or rearranged structure.

Example of a Radical Mechanism:

If a molecule with a radical at one end undergoes a [1,7] hydrogen migration, the hydrogen atom shifts over six atoms, potentially stabilizing the radical center. For instance:

\text{CH₃–CH₂–CH₂·} \xrightarrow{\text{[1,7] hydrogen migration}} \text{CH₂=CH–CH₂·}

Here, the radical on carbon 3 can migrate to carbon 7, stabilizing the molecule through the migration of a hydrogen atom.

Cyclization Reactions:
- The [1,7] hydrogen shift can also be involved in cyclization reactions where a hydrogen atom migrates across a long chain to form a new ring structure. The shift of the hydrogen atom can promote ring closure or form conjugated systems.

Examples of [1,7] Hydrogen Migration in Organic Chemistry

1. Cycloheptatriene Derivatives

2. [1,7] Hydrogen Migration in Diene Systems

In systems such as dienes, where there are conjugated double bonds, [1,7] hydrogen migrations can lead to conjugation and ring closure:

\text{CH₂=CH–CH₂–CH₂–CH₂–CH₂–CH₂} \xrightarrow{\text{[1,7] hydrogen migration}} \text{CH₂=CH–CH₂–CH₂–CH=CH₂}

Stereochemistry of [1,7] Hydrogen Migration

The stereochemistry of [1,7] hydrogen migration depends on the specific reaction mechanism:

Concerted Mechanisms (e.g., in sigmatropic rearrangements): The migration typically occurs in a stereospecific manner. The transition state must involve the simultaneous movement of atoms, leading to a specific stereochemistry in the final product.
Radical Processes: In radical mechanisms, the migration may be non-stereoselective, leading to a mixture of stereoisomers. The radical intermediate can lead to different possible configurations of the final product, as the hydrogen atom may migrate in any direction along the chain.

Applications of [1,7] Hydrogen Migration

Synthesis of Complex Molecules:
- The [1,7] hydrogen migration plays a crucial role in the synthesis of complex organic molecules, including the formation of cyclic compounds and conjugated systems. These shifts enable the formation of stable intermediates and contribute to the functionalization of molecules.
Stabilization of Radicals:
- In radical chain processes, [1,7] hydrogen migrations help stabilize the radical intermediates, leading to more favorable reaction pathways and the formation of stable products.
Cyclization and Aromatization:
- The [1,7] hydrogen migration can be essential in cyclization reactions, facilitating ring closure or aromatization. These processes are important in the synthesis of aromatic compounds or heterocyclic structures.
Conjugated Systems:
- The migration of hydrogen atoms across long distances, such as the [1,7] shift, can help create or stabilize conjugated systems, which are valuable in organic electronic devices and photochemical reactions.

Conclusion

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[1,5] Hydrogen Migration

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[1,9] Hydrogen Migration

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