All products and services

C=C double bond reduction kit

This kit contains 7 ene reductase (ENE) enzymes for the reduction of C=C double bonds in the presence of an electron withdrawing group (EWG).

Ir-94

CAS Number: 41396-69-4 | [IrCl(COD)Phen] · THF

Rh-95, rhodium (acetylacetonato)(1,5-cyclooctadiene)

Rhodium(2,4-pentanedionate)(1,5-cyclooctadiene) | CAS: 12245-39-5

Ru-721

CAS Number: 850424-32-7

Catalyst enhancement FCC additive

CAT-AID, Johnson Matthey’s catalyst enhancement additive, is designed to overcome many of the shortcomings related to deactivation of base catalyst from metal contaminants such as vanadium, nickel, iron, calcium, sodium, and potassium.

10R394

10R487

5R39

5R424

A402028-10 |10% Palladium/Carbon

10% Palladium/Carbon

A405028-5

A405032-5

A503023-5

B312099-5

10R39

1R128M

A302011-5

Oxidation technology

In terms of organic chemistry, oxidation is defined as a reaction which causes carbon to lose electron density. This can be caused by a carbon atom forming a bond with a more electronegative atom (e.g. oxygen, nitrogen), or breaking a bond with a less electronegative atom (e.g. hydrogen).

Communities

Butanediol BDO THF GBL DMS process, Hydrogenolysis and Esterification technology

Johnson Matthey is the leading technology provider for butanediol plants worldwide. The DAVY™ butanediol process can produce in a single reaction train, varying ratios of three products; 1,4 butanediol (BDO), tetrahydrofuran (THF), Di-methyl succinate (DMS) and gamma butyrolactone (GBL). Hydrogenolysis is a reaction where hydrogen is added to a compound and breaks that compound’s bonds, forming two molecules as a result. Johnson Matthey's DAVY™ hydrogenolysis technology reacts hydrogen gas (H2) with a vapour-phase carbonyl compound. Esters are organic compounds characterized by the RCOOR’ functional group, and are most commonly derived from the reaction of carboxylic acids with alcohols.

Product stewardship

Ruthenium nitrosyl nitrate solution

CAS: 34513-98-9

Ethanolamine hexahydroxyplatinic acid (Platinum EA solution)

Ethanolamine hexahydroxyplatinic acid

Achieving net zero by 2040

BPC-307

P(Ad)2(nBu) A Gen 3 | CAS # 1651823-59-4

Health and safety

Membrane electrode assembly (MEA)

MEA solutions for your fuel cell system.

Gold bromide solid

Hydrogen tetrabromoaurate(III) solid | CAS: 10294-28-7

Pd-119

CAS Number: 215788-65-1 | PdCl2 (dippf)

Pd-140

PdCl2 (DCEPhos) | CAS Number: 69861-71-8

Hydrogenation technology

Hydrogenation is a key part of the oxo alcohols process for the production of oxo alcohols, where aldehyde produced by hydroformylation or aldolisation is hydrogenated to produce oxo alcohols.

Dehydrogenation technology

While various dehydrogenation pathways exist for different compounds, Johnson Matthey's DAVY™ technology focusses on alcohol dehydrogenation to yield an ester product.

Vinyl chloride monomer (VCM) process

Johnson Matthey offers a well-established VCM technology which is recognised by industry as the most advanced acetylene-to-VCM process worldwide.

Hydrochlorination technology

Hydrochlorination involves adding hydrogen chloride across the multiple bond of an unsaturated hydrocarbon. Johnson Matthey's DAVY™ hydrochlorination technology focuses on alkyne (triple-bonded) reactants.

Fischer Tropsch technology

Johnson Matthey have collaborated with BP to produce our proprietary fixed-bed Fischer Tropsch (FT) technology – a simple and robust system which forms the heart of our gas-to-liquids (GTL) process.

CANS novel reactors technology

Johnson Matthey has developed a novel DAVY™ reactor design that provides increased efficiency whilst significantly reducing vessel sizes, equipment count and catalyst volumes.

Methanation technology

Our methanation technology, utilising our CRG catalysts , performs the key chemical transformation of syngas into SNG, and ensures the final product is of a suitable quality for injection into gas distribution networks.

Methanation catalysts

Methanation is the reaction by which carbon oxides and hydrogen are converted to methane and water. The reaction is catalysed by nickel catalysts. In industry, there are two main uses for methanation, to purify synthesis gas (i.e. remove traces of carbon oxides) and to manufacture methane.