Cumene is formed in the gas-phase
Friedel–Crafts alkylation of benzene by propene. Benzene and propene are compressed together to a pressure of 30 bar at 250 °C in presence of a
catalytic Lewis acid.
Phosphoric acid is often favored over
aluminium halides. Cumene is oxidized in air, which removes the tertiary
benzylic hydrogen from cumene and hence forms a cumene
radical: :: The cumene radical then
bonds with an oxygen molecule to give cumene
peroxide radical, which in turn forms
cumene hydroperoxide (C6H5C(CH3)2O2H) by abstracting a benzylic hydrogen from another cumene molecule. This latter cumene converts into cumene radical and feeds back into subsequent chain formations of cumene hydroperoxides. A pressure of 5
atm is used to ensure that the unstable peroxide is kept in liquid state. :: :: Cumene hydroperoxide undergoes a
rearrangement reaction in an
acidic medium (the
Hock rearrangement) to give
phenol and
acetone. In the first step, the terminal hydroperoxy oxygen atom is protonated. This is followed by a step in which the phenyl group migrates from the benzyl carbon to the adjacent oxygen and a water molecule is lost, producing a
resonance stabilized tertiary
carbocation. The concerted mechanism of this step is similar to the mechanisms of the
Baeyer–Villiger oxidation and
Criegee rearrangement reactions, and also the oxidation step of the
hydroboration–oxidation process. In 2009, an acidified
bentonite clay was proven to be a more economical catalyst than
sulfuric acid as the acid medium. :: The resulting
carbocation is then attacked by water, forming a
hemiacetal-like structure. After transfer of a proton from the hydroxy oxygen to the ether oxygen, the ion falls apart into phenol and acetone. :: ==Related reactions and modifications==