The present invention relates to the preparation of perfluorinated or partially fluorinated peroxides which avoids the use of carbonyl fluoride (COF.sub.2).

The present invention provides a method of making carboxylic acids from levulinic acid, such as succinic acid and 3-hydroxypropanoic acid, by reacting levulinic acid with an oxidant such as hydrogen peroxide under acidic or basic conditions.

The present invention provides a method of making carboxylic acids from levulinic acid, such as succinic acid and 3-hydroxypropanoic acid, by reacting levulinic acid with an oxidant such as hydrogen peroxide under acidic or basic conditions.

The present invention provides a method of making carboxylic acids from levulinic acid, such as succinic acid and 3-hydroxypropanoic acid, by reacting levulinic acid with an oxidant such as hydrogen peroxide under acidic or basic conditions.

Provided are processes for preparing alpha, beta-unsaturated functional compounds using four major reaction steps: 1) air oxidation of an iso-paraffin to a mixture of alkyl hydroperoxide and alcohol; 2) converting the alkyl hydroperoxide and alcohol to dialkyl peroxide; 3) oxidative cross-coupling between a primary or secondary alcohol and a compound comprising at least one R3CH2- (R3=hydrogen or an optionally substituted hydrocarbyl) moiety to afford a coupled product using the dialkyl peroxide as a radical initiator, while the dialkyl peroxide is converted to a tertiary alcohol; 4) dehydration of the coupled product to yield an alpha, beta-unsaturated functional compound.

Provided are processes for preparing alpha, beta-unsaturated functional compounds using four major reaction steps: 1) air oxidation of an iso-paraffin to a mixture of alkyl hydroperoxide and alcohol; 2) converting the alkyl hydroperoxide and alcohol to dialkyl peroxide; 3) oxidative cross-coupling between a primary or secondary alcohol and a compound comprising at least one R3CH2- (R3=hydrogen or an optionally substituted hydrocarbyl) moiety to afford a coupled product using the dialkyl peroxide as a radical initiator, while the dialkyl peroxide is converted to a tertiary alcohol; 4) dehydration of the coupled product to yield an alpha, beta-unsaturated functional compound.

An integrated process for the preparation of carboxylic acids using iso-paraffins is provided. The process includes oxidatively carbonylating a compound having a carbon-hydrogen bond with dialkyl peroxide, carbon monoxide and water. Concurrently, the iso-paraffin is converted to iso-alcohol. The process provides access to a wide range of useful carboxylic acids and operates under relatively mild conditions.

An integrated process for the preparation of carboxylic acids using iso-paraffins is provided. The process includes oxidatively carbonylating a compound having a carbon-hydrogen bond with dialkyl peroxide, carbon monoxide and water. Concurrently, the iso-paraffin is converted to iso-alcohol. The process provides access to a wide range of useful carboxylic acids and operates under relatively mild conditions.

Methods for preparing isotopically modified 1,4-diene systems from non-isotopically modified 1,4-dienes involve selective oxidation of one or more bis-allylic position(s), or the preparation of isotopically modified 1,4-diene systems via trapping pi-allylic complexes with a source of deuterium or tritium. Such methods are useful for preparing isotopically modified polyunsaturated lipid including polyunsaturated fatty acids and polyunsaturated fatty acid derivatives.

Methods for preparing isotopically modified 1,4-diene systems from non-isotopically modified 1,4-dienes involve selective oxidation of one or more bis-allylic position(s), or the preparation of isotopically modified 1,4-diene systems via trapping pi-allylic complexes with a source of deuterium or tritium. Such methods are useful for preparing isotopically modified polyunsaturated lipid including polyunsaturated fatty acids and polyunsaturated fatty acid derivatives.