This invention relates to a method for the conversion of lignocellulosic biomass into ethyl esters of carboxylic acids. Said method consists of treating the biomass material with an oxidizing agent that is incorporated in an solution comprising one or more acids, one or more alcohols and water, and subsequently performing a catalytic reaction at a higher temperature using the same acidic solution into which a larger volume of alcohol is added, in such a way that the catalytic conversion occurs in a medium with a much higher concentration of alcohol, i.e. with a much higher alcohol-to-water wt ratio. Such a method results in relatively high yields of ethyl esters, such as ethyl esters of formic, acetic, and levulinic acids, while producing a low yield of dialkyl ethers, which are unwanted by-products. The concentration of the oxidizing agent in the pre-treatment step is preferably higher than 6.0 wt %. The oxidizing agent is preferably a Fenton or Fenton-type reagent, and most preferably hydrogen peroxide activated by Fe (II), and/or Ti (IV) ions. The alcohol is preferably ethanol, and when ethanol is used, diethyl ether is formed as the unwanted dialkyl ether by-product. Preferably, the biomass material is pelleted before treatment.

This invention relates to a method for the conversion of lignocellulosic biomass into ethyl esters of carboxylic acids. Said method consists of treating the biomass material with an oxidizing agent that is incorporated in an solution comprising one or more acids, one or more alcohols and water, and subsequently performing a catalytic reaction at a higher temperature using the same acidic solution into which a larger volume of alcohol is added, in such a way that the catalytic conversion occurs in a medium with a much higher concentration of alcohol, i.e. with a much higher alcohol-to-water wt ratio. Such a method results in relatively high yields of ethyl esters, such as ethyl esters of formic, acetic, and levulinic acids, while producing a low yield of dialkyl ethers, which are unwanted by-products. The concentration of the oxidizing agent in the pre-treatment step is preferably higher than 6.0 wt %. The oxidizing agent is preferably a Fenton or Fenton-type reagent, and most preferably hydrogen peroxide activated by Fe (II), and/or Ti (IV) ions. The alcohol is preferably ethanol, and when ethanol is used, diethyl ether is formed as the unwanted dialkyl ether by-product. Preferably, the biomass material is pelleted before treatment.

The invention relates to a process for the conversion of furfuryl alcohol into a levulinate ester comprising contacting furfuryl alcohol; an alcohol, or a mixture thereof; and a homogeneous catalyst at a first reaction temperature in the range of from 125 to 180° C. to form a reaction mixture; and forming the levulinate ester in the reaction mixture, characterised in that the first homogeneous catalyst is a sulfonic acid catalyst.

The invention relates to a process for the conversion of furfuryl alcohol into a levulinate ester comprising contacting furfuryl alcohol; an alcohol, or a mixture thereof; and a homogeneous catalyst at a first reaction temperature in the range of from 125 to 180° C. to form a reaction mixture; and forming the levulinate ester in the reaction mixture, characterised in that the first homogeneous catalyst is a sulfonic acid catalyst.

A process is provided for the preparation of value added chemicals such as ethyl levulinate from a glucose or other sugars, catalyzed by a mixture of a Lewis acid catalyst and a Bronsted acid catalyst.

A process is provided for the preparation of value added chemicals such as ethyl levulinate from a glucose or other sugars, catalyzed by a mixture of a Lewis acid catalyst and a Bronsted acid catalyst.

A process is provided for the preparation of value added chemicals such as ethyl levulinate from a glucose or other sugars, catalyzed by a mixture of a Lewis acid catalyst and a Bronsted acid catalyst.

A process for producing levulinic acid includes a step of catalytic conversion of a pentose (in particular xylose or arabinose) into furfural in an organic solvent having a boiling temperature from 60° C. to 220° C., followed by a step of reduction of furfural to furfuryl alcohol, in the presence of a Lewis acid as catalyst and a protic solvent. Eventually, furfuryl alcohol is converted into levulinic acid directly or indirectly, by preliminary conversion into a levulinic acid ester and its subsequent hydrolysis. This process has a reduced environmental impact and guarantees satisfactory process yields on an industrial scale. In particular, the process allows to reduce as much as possible the formation of humins, which require complex and costly purification processes and involve a considerable reduction in the levulinic acid yields.

A process for producing levulinic acid includes a step of catalytic conversion of a pentose (in particular xylose or arabinose) into furfural in an organic solvent having a boiling temperature from 60° C. to 220° C., followed by a step of reduction of furfural to furfuryl alcohol, in the presence of a Lewis acid as catalyst and a protic solvent. Eventually, furfuryl alcohol is converted into levulinic acid directly or indirectly, by preliminary conversion into a levulinic acid ester and its subsequent hydrolysis. This process has a reduced environmental impact and guarantees satisfactory process yields on an industrial scale. In particular, the process allows to reduce as much as possible the formation of humins, which require complex and costly purification processes and involve a considerable reduction in the levulinic acid yields.

The present disclosure provides improved methods of performing ozonolysis on alkenes comprising non-reductive quenching of ozonide intermediates using Bronsted bases to yield aldehyde, ketone and/or carboxylic acid products.