All products and services

Ru-721

[DPPB RuCl₂ AMPY], Baratta's Catalyst | CAS Number: 850424-32-7

Pd-111NP

CAS Number: 3375-31-3 | Pd(OAc)2

Pd-215

[RockPhos Pd(allyl)]OTf | CAS Number: 1798782-31-6

Pd-215

[Me₃OMetBuXPhos Pd(allyl)]OTf | CAS Number: 2924017-86-5

Pd-203

Bis(tri-tert-butylphosphine)palladium(0) | CAS Number: 2548904-17-0

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.

BPC-307

CataCXium A Pd G3 | CAS # 1651823-59-4

Pd-119

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

Pd-214

[Me₄tBuXPhos Pd(allyl)]OTf | CAS Number: 1798782-29-2

RTA-194: R-transaminase

Aromatic and aliphatic primary amines can be obtained using our Transaminases

Glucose dehydrogenase enzymes

GDH enzymes catalyses the oxidation of D-glucose to D-glucolactone, while reducing in turn NAD+ or NADP+ to NADH and NADPH.

Pi-allyl palladium complexes

Triflate and chloride pi-allyl palladium products

Buchwald precatalysts

Second and third generation buchwald precatalysts for advanced cross-coupling applications.

Palladium coupling precatalysts - PdL2X2

Bis-phosphine palladium halide pre-catalysts for basic cross coupling applications.

DyadPalladate™ precatalysts

Bisphosphonium dichloropalladate complexes featuring tertiary phosphonium ligands

Alcohol dehydrogenase enzymes

ADH enzymes used to catalyse the reduction of ketones and aldehydes to the corresponding alcohols

Imine reductases enzymes

Imine reductases (IREDs) biocatalysts are used to produce enantiopure primary, secondary and tertiary amines

Glucose dehydrogenase enzymes

Glucose dehydrogenase catalyses the oxidation of D-glucose to D-glucolactone

Formate dehydrogenase enzymes

Formate dehydrogenase (FDH enzyme) oxidises formate to carbon dioxide

Ene reductase enzymes

Ene reductase enzyme catalyse the reduction of C=C double bonds

Transaminase enzymes

Transaminase enzymes can be used to produce aromatic and aliphatic primary amines.

Alanine dehydrogenase enzyme

Alanine dehydrogenase catalyses the reductive amination of pyruvate to L-alanine

Amine dehydrogenase enzymes

Amine dehydrogenase enzymes are wild type and engineered enzymes to catalyse a wider range of transformations

Lactate dehydrogenase enzymes

Lactate dehydrogenase catalyses the reduction of pyruvate to either (R)- or (S)- lactate

Equilibrium shift enzymes

We offer multi-enzymatic systems to remove the pyruvate by-product from the reaction

Cofactor regeneration enzymes

NADP and NAD regeneration enzymes

Standard SCR NOx Control Systems

Purification by catalytic oxidation

Our PURAVOC™ technology provides a catalytic oxidation solution to remove a broad variety of volatile organic compounds (VOCs), oxygen, hydrogen and carbon monoxide from various gas stream sources.

PGM Platinum

Platinum is used in a wide variety of applications with platinum jewellery accounting for almost a quarter of annual platinum demand, but the largest use is in automotive catalytic converters..

1R128M

B312099-5

10R424

PRECISION Methanol technology

Our PRECISION Methanol process is based on autothermal reforming, and it is the best solution for lighter feedstocks with low levels of CO2 and inert gases. It achieves high natural gas efficiency without the need to import H2, delivering low OPEX, economy of scale and the fastest pay-back time for medium to large methanol capacities.

Waste to methanol

Waste is a source of valuable carbon and hydrogen that can be transformed into methanol. This reduces the amount of waste destined to landfill and incineration and replaces natural gas and coal-based feedstocks, enabling the production of more sustainable fuels and chemicals with a lower carbon footprint.

CO2 to methanol

Methanol produced using electrolytic hydrogen is an attractive alternative and potentially carbon neutral fuel. It can be directly used as a road and maritime transportation fuel or as a low carbon intensity intermediate to produce Sustainable Aviation Fuel (SAF) or green gasoline.

SWITCH Methanol technology

Johnson Matthey’s award-winning SWITCH Methanol process delivers minimal direct CO2 emissions without the additional investment, running costs and complexity of carbon capture. It is ready to receive renewable electricity and it enables methanol producers to meet their sustainability goals as we transition to a low-carbon economy.

FLEXI Methanol technology

Our FLEXI Methanol process is a robust technology for medium to large capacity plants which delivers consistent, high performance and which is used today in the most energy efficient methanol plants in the world.

PRIMARY Methanol technology

Our well-established PRIMARY Methanol process is an oxygen-free solution based on the use of a steam methane reformer (SMR). It is the technology of choice when the feedstock has a high CO2 content or a source of CO2 import is available, delivering up to 5,600 MTPD of methanol in a single train without an air separation unit.

Methanol and ammonia co-production

Partnering with KBR under a global strategic alliance, we license a ground-breaking ammonia-methanol co-production solution which combines our market leading technologies: Johnson Matthey’s PRIMARY Methanol process and KBR’s PURIFIER ammonia technology.

low-carbon-solutions

Johnson Matthey's low carbon solutions: Decarbonising the installed asset base with ready-now solutions

Methanol

Methanol is an important and highly versatile chemical used to produce hundreds of every-day products which improve our quality of life, such as plywood, paint and adhesives. It is also a clean-burning and safe alternative to conventional fuels and a potential enabler for decarbonization.

SILVER-FLO filler metals

SILVER-FLO™ products can be used to join the common engineering metals such as copper, copper alloys (brass, bronze, nickel silver, aluminium bronze, copper nickel), nickel alloys, steel, stainless steel and tungsten carbide.

Rh-93

CAS Number: 12092-47-6

ARGO-BRAZE™ filler metals

ARGO-BRAZE™ products are most commonly used for brazing cemented tungsten carbide and tungsten carbide faced PCD tips.

PALLABRAZE - filler metals

PALLABRAZE™ products can be used to braze a variety of materials from stainless steel to metalised ceramics.

Ir-70

Ir(acac)₃ | CAS 15635-87-7

Ir-95

[Ir(cod)(Me₄phen)]Cl • THF | CAS 15635-87-7

Ir-121

[Ir(Cp*)I₂]₂ | CAS 33040-12-9

Ir-121

Ir(C₈H₁₂){PCH₃(C₆H₅)₂}₂PF₆ | CAS 38465-86-0

Ir-125

[Ir{dF(CF₃)ppy}₂(dtbbpy)][PF₆] | CAS # 870987-63-6

Ir-127

IrCl(COD)(dppe) | CAS 688063-93-6

Ir-125

[Ir(ppy)₂(dtbbpy)][PF₆] | CAS # 676525-77-2

Ni-130

[(TMEDA)Ni(o-tolyl)Cl], Doyle's Catalyst | CAS 1702744-45-3

Substitute natural gas (SNG) process

With over 20 years' experience, Johnson Matthey is the market leader in the supply of SNG catalysts and technology, with our DAVY™ licensed plants providing more than half of global SNG production.

Ni-103

NiCl₂(dppe) | CAS 14647-23-5

Ni-107

NiCl₂(dppf) | CAS 67292-34-6

Ni-114

NiCl2(PCy3)2 | CAS 19999-87-2

Ni-114

NiCl2(dppp) | CAS 19999-87-2

Ni-126

NiCl₂(dppp) | CAS 15629-92-2

Ni-127

NiCl2(dcypf) | CAS 917511-89-8