Free-radical addition

Free-radical addition is an addition reaction in organic chemistry involving free radicals.^[1] The addition may occur between a radical and a non-radical, or between two radicals.

The basic steps with examples of the free-radical addition (also known as radical chain mechanism) are:

Initiation by a radical initiator: A radical is created from a non-radical precursor.
Chain propagation: A radical reacts with a non-radical to produce a new radical species
Chain termination: Two radicals react with each other to create a non-radical species

Free-radical reactions depend on a reagent having a (relatively) weak bond, allowing it to homolyse to form radicals (often with heat or light). Reagents without such a weak bond would likely proceed via a different mechanism. An example of an addition reaction involving aryl radicals is the Meerwein arylation.

Addition of mineral acid to an alkene

To illustrate, consider the alkoxy radical-catalyzed, anti-Markovnikov reaction of hydrogen bromide to an alkene. In this reaction, a catalytic amount of organic peroxide is needed to abstract the acidic proton from HBr and generate the bromine radical, however a full molar equivalent of alkene and acid is required for completion.

Note that the radical will be on the more substituted carbon. Free-radical addition does not occur with the molecules HCl or HI. Both reactions are extremely endothermic and are not chemically favored.

Self-terminating oxidative radical cyclizations

In one specific type of radical addition called self-terminating oxidative radical cyclization, alkynes are oxidized to ketones with intramolecular radical cyclization and the radical species are inorganic rather than carbon based. This type of reaction is self-terminating because propagating is not possible and the initiator is used in stoichiometric amounts.^[2]

As an example a nitrate radical is generated by photolysis of CAN which reacts with an alkyne to generate first a very reactive vinyl radical and then via a 1,5-hydrogen atom transfer (HAT) and 5-exo-trig ring-closure a ketyl radical. The ketyl dislodges a nitrite radical which is not reactive enough for propagation and the ketone is formed.

The radical species in effect is a single oxygen atom synthon. Other inorganic radicals that show this type of reactivity are sulfate radical ions (from ammonium persulfate) and hydroxyl radicals.

References

↑ L.G. Wade's Organic Chemistry 5th Ed. (p 319) – Mechanism supplements original.
↑ Self-Terminating, Oxidative Radical Cyclizations Tim Dreessen, Christian Jargstorff, Lars Lietzau, Christian Plath, Arne Stademann and Uta Wille Molecules 2004, 9, 480–497 Online article

Basic reaction mechanisms

Nucleophilic substitutions	Unimolecular nucleophilic substitution (S_N1) Bimolecular nucleophilic substitution (S_N2) Nucleophilic aromatic substitution (S_NAr) Nucleophilic internal substitution (S_Ni) Nucleophilic acyl substitution

Elimination reactions	Unimolecular elimination (E1) E1cB-elimination reaction Bimolecular elimination (E2)

Addition reactions	Electrophilic addition Nucleophilic addition Free-radical addition Cycloaddition

Related topics	Elementary reaction Molecularity Stereochemistry Catalysis Collision theory Solvent effects Arrow pushing

Chemical kinetics	Rate equation Rate-determining step

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Free-radical addition

Addition of mineral acid to an alkene

Self-terminating oxidative radical cyclizations

See also

References