Copyright © 1999-2019 John Wiley & Sons, Inc. All rights reserved

Used in a wide number of industries, coatings not only provide countless items with color and texture, but also enhance their appearance and prolong their life.

Specialty molecules known as functional monomers can provide a standard polymer with additional, enhanced performance effects and/or significantly improve processing performance when incorporated into the polymerization process.

DCPD (dicyclopentadiene) type is mainly used as an epoxy resin modifier (ERM) in epoxy chain-extending reactions, primarily for the manufacture of epoxy composites.

Bisphenol type is used in the manufacture of numerous plastics and epoxy resins. Applications for bisphenol-based plastic, which is clear and tough, include a variety of common consumer goods, such as water bottles, sports equipment, CDs, and DVDs. Epoxy resins containing bisphenols are used to line water pipes and coatings, and in the manufacture of thermal paper, such as that used in sales receipts.

Fluorene type is highly suitable as components of a conducting polymer because they can stabilize and conduct a charge. The luminescent, electronic and absorptive properties of fluorene make it attractive for devices such as organic light-emitting diodes (OLEDs), organic solar cells, and organic thin-film sensors.

Pharmaceutical intermediates are the chemical composites that are major ingredient exploited in the manufacturing of active pharmaceutical ingredients. Pharmaceutical intermediates are formed at the time of process of production or synthesis of active pharmaceutical ingredients. These pharmaceutical intermediates later endure molecular changes and processing before becoming a vigorous pharmaceutical ingredient.

Market Dynamics

Pharmaceutical industry is one of the rapidly nurturing industry, globally. As pharmaceutical intermediates are the fundamental base part of active pharmaceutical ingredients (APIs), the market for API is also expected to witness upsurge in demand in foreseeable years. API market is a very vigorous and from the last few years, there has been a drastic inclination in the direction of research and development activities. Owing to the growth in R&D sector, pharmaceutical intermediates market is projected to reflect a drastic growth. However, rising monetary pressure as well as regulatory obstruction is expected to freeze the growth of pharmaceutical intermediates market.

Market Classification

On the basis of product type, pharmaceutical intermediates market can be segmented into building block structure, end user and region. Based on the building block structure, the global pharmaceutical intermediate market can be divided into achiral building block and chiral building block. Further, on the basis of end users, the pharmaceutical intermediates market can be portioned into pharmaceutical organizations, research labs, contract manufacturing associations and different businesses. The global market for pharmaceutical intermediates is expected to showcase remarkable rise during the estimated period. Additionally, larger manufacturing of dynamic pharmaceutical ingredients are dependent upon pharmaceutical intermediates which is further expected to propel the market growth. Based on geography, market is partitioned into North America, Latin America, Europe, Asia-Pacific and Middle East &Africa.

The precious metal catalyst is a precious metal material that can change the speed of chemical reaction without participating in the final product. Almost all precious metals can be used as catalysts, but platinum (CAS: 7440-06-4), palladium (CAS: 7440-05-3), ruthenium (CAS: 7440-18-8), rhodium (CAS: 7440-16-6), iridium (CAS: 7439-88-5), gold (CAS: 7440-57-5) and silver (CAS: 7440-22-4) are commonly used, especially platinum (CAS: 7440-06-4) and palladium (CAS: 7440-05-3). It is an important catalyst material because of its high catalytic activity, high-temperature resistance, oxidation resistance, and corrosion resistance.

Composition
Features
² Easy adsorption of reactants, high catalytic activity

² Low heat of formation, weak binding force to oxygen and hydrogen, desorption is fast

² Good thermal stability, a wide range of applicable temperature

² High chemical stability, not easy to be REDOX, not easy to be corroded

² Has a variety of catalytic activities (such as photocatalysis, electrocatalysis, etc.)

Classification
According to the category of catalytic reaction, it can be divided into homogeneous catalysis and heterogeneous catalysis. Homogeneous catalysts are usually soluble compounds (salts or complexes), such as palladium chloride (CAS: 7647-10-1), rhodium chloride (CAS: 20765-98-4), palladium acetate (CAS: 3375-31-3), carbonyl rhodium (CAS: 28407-51-4), triphenylphosphine carbonyl rhodium (CAS: 17185-29-4), rhodium iodide (CAS: 15492-38-3), etc. Heterogeneous catalysts are insoluble solids, and their main forms are wire mesh state and metal state supported by porous inorganic carriers. Metal mesh catalysts (such as platinum mesh, platinum-rhodium alloy mesh, etc.) have limited application range and dosage. Most heterogeneous catalysts are supporting precious metals, such as Pt/Al2O3, Pd/C (CAS: 7440-05-3), Rh/SiO2, Pt-Pd/Al2O3, Pt-Rh/Al2O3, etc. Among all catalytic reactions, heterogeneous catalytic reactions account for 80% ~ 90%. According to the shape of the carriers, the supported catalysts can be divided into particle, ball, column, and honeycomb.

According to the main active metal of catalysts, it can be classified: platinum catalyst, palladium catalyst, rhodium catalyst, ruthenium catalyst and so on.

Application
Due to their irreplaceable catalytic activity and selectivity, precious metal catalysts play an extremely important role in petroleum, chemical industry, medicine, pesticide, food, environmental protection, energy, electronics, and other fields.

Precious metals are excellent catalysts for hydrogenation reduction, oxidative dehydrogenation, catalytic reforming, hydrogenation cracking, hydrodesulfurization, reductive amination, polymerization, coupling, disproportionation, ring expansion, cyclization, carbonylation, formylation, dechlorination and asymmetric synthesis in petroleum and chemical industries.

In the field of environmental protection, precious metal catalysts are widely used in automobile exhaust purification, organic catalytic combustion, CO/NO oxidation and so on.

The precious metal catalyst is the most important part of the development of a new fuel cell.

Precious metal catalysts are used for gas purification in the fields of electronics and chemical engineering.

At present, catalytic technology is one of the advanced technologies, which can also produce huge economic and social benefits.

20%~30% of the gross national economic output of developed countries directly comes from catalysts and catalytic reactions.

More than 85% of the reactions in the production of chemical products are carried out under the action of the catalyst.

Precious metal catalysts have broad application prospects in the research and development of new fields of chemistry.