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Hydrogen Peroxide is a major industrial chemical that is primarily used as a disinfectant and is incorporated into industrial and household activities. The chemical exhibits excellent oxidizing properties and is very effective against harmful bacteria, viruses, and other microorganisms. It is a colorless to pale blue color aqueous chemical compound that has a slightly bitter taste. It is highly soluble in water and chemical solvents, such as ether. However, the compound remains insoluble in petroleum ether. It is incorporated with bleaching, cleaning, disinfecting, and chemical manufacturing activities on a large scale.
Hydrogen peroxide is a commercial chemical that is majorly correlated with several industrial domains in the global market. It is incorporated into healthcare and medication sectors, where it is majorly used as a disinfectant and cleans wounds and injuries. It is also linked with the paper and pulp industry for carrying out bleaching activities and in the electronics sector for etching circuit boards. It is widely included in manufacturing cosmetics and chemicals, leading to large-scale production.
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Let’s roll down the list of top 10 leading manufacturers of hydrogen peroxide in the world
It is a leading chemical company that stands as a key manufacturer of hydrogen peroxide. It is a global leader with around three business segments under it, which typically contains chemicals, materials, and solutions. The company was founded in the year 1862, with its headquarters being placed in Brussels, Belgium. It is also associated with industrial segments like aerospace, automotive, electronic, and more.
It is a leading multinational company with a specialty in the chemical manufacturing domain. The company is located in Essen, Germany, and was established in 2007. It has production plants in 27 different countries across the world. It is associated with technology, infrastructure, food, and nutritional sectors on a large scale.
The company is one of the top manufacturers of hydrogen peroxide in the world. The company’s headquarter is located in Colombes, France. It was established in the year 2004. Arkema is specialized in material science and manufacturing units. It is correlated with chemical manufacturing and operates mainly with specialty materials on a large scale.
Kimra is a manufacturer that produces hydrogen peroxide chemicals on a vast scale. It is one of the leading producers of the key chemical across the world. The company is situated in Helsinki, France, and was established in the year 1920. It is a chemical company that aims to provide solutions based on sustainable chemical sources. It is typically correlated with various other industrial sectors, including paper and pulp, oil, and chemical domain.
Mitsubishi Gas Chemical company is a chemical manufacturing firm that produces hydrogen peroxide on a large scale. It is mostly associated with chemical manufacturing activities, upbringing various commercial chemicals, and processing them to be marketed on a global scale. It is correlated with plastic manufacturing as well as petrochemical manufacturing domains.
Akzo Nobel N.V. is one of the leading multinational companies that produces hydrogen peroxide chemicals on a large scale. The company is situated in various countries across the globe, with its headquarters located in Amsterdam, Netherlands. It was established in the year 1994. It is mainly associated with various other sectors and primarily marks incorporation with chemical, paper, and paint manufacturing industries.
The company is a manufacturer and distributor of hydrogen peroxide chemical compounds and is widely associated with other industrial sectors, including pharmaceutical and chemical domains. The headquarter is situated in Avon, Ohio, and the company was established in the year 1957. It is also associated with the agricultural, food manufacturing, and electronics sectors on a large scale.
It is a multinational company with its headquarters situated in California, USA. The company was founded in the year 2010. Evonik is one of the major manufacturers of hydrogen peroxide compounds and is also associated with various industries, including the chemical, paper, oil, and gas sectors.
It is a multinational company with a headquarter located in Bangkok, Thailand. It was established in the year 1994. The company is a leading producer of hydrogen peroxide chemical compounds and is primarily associated with paper, chemical, textile manufacturing, and petrochemical industries.
It is one of the largest and most prominent chemical manufacturers across the globe. It produces hydrogen peroxide, along with various other essential industrial chemicals, on a large scale. The company is established in the year 1865. It is associated with finding sustainable energy solutions that can be incorporated into chemical manufacturing units.
Hydrogen peroxide, recognized for its chemical versatility, has established a significant footprint in diverse industrial sectors, spanning healthcare to aerospace engineering. From its role in sterilization protocols to its utility as a rocket oxidizer, its wide-ranging applications emphasize its adaptability and technical importance. As the industrial landscape undergoes rapid technological metamorphosis, hydrogen peroxide's relevance is poised to amplify. Its attributes in clean bleaching processes and its potential in emerging energy paradigms further validate its indispensability. Moving forward, industry professionals can anticipate an even broader spectrum of applications for hydrogen peroxide, catalyzing advancements and setting novel industrial benchmarks.
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The big brown bottle of hydrogen peroxide (H2O2) is a staple of the modern medicine cabinet, always on hand for first aid needs. Lesser known uses of hydrogen peroxide include disinfecting hospital equipment and fueling spacecraft. Yet as common and beneficial of a substance as it is, hydrogen peroxide is surprisingly hard to produce and transport.
Currently, hydrogen peroxide is made through what’s known as the “anthraquinone process.” This method is energy-intense, requires large-scale production, and produces large quantities of carbon dioxide (CO2) as a byproduct. While directly reacting hydrogen and oxygen to make hydrogen peroxide would be ideal, thermodynamics prefers to form the more stable water (H2O) over hydrogen peroxide.
So the challenge becomes: does a material exist that can be used to selectively, reliably, and efficiently form hydrogen peroxide whenever and wherever it’s needed, so that transporting it isn’t necessary?
A team of researchers from Carnegie Mellon University has set out to meet that difficult challenge. Associate Professors Venkat Viswanathan (mechanical engineering) and Tzahi Cohen-Karni (biomedical engineering/materials science and engineering) are leading an effort to develop a cheap, renewable, and sustainable method of creating hydrogen peroxide. The team has published a paper in ACS Catalysis on the work.
With our method we hope to provide the capability of making hydrogen peroxide when you need it, wherever you are.
Venkat Viswanathan, Associate Professor, Mechanical Engineering
“The most difficult thing about hydrogen peroxide is transporting it,” explains Viswanathan. “Hospitals and space missions have particular uses for hydrogen peroxide, including rapid sterilization and as an oxidant. Transport of hydrogen peroxide to hospitals can be dangerous and complicated, and you can’t take gallons of oxidants into space due to weight restrictions, so with our method we hope to provide the capability of making hydrogen peroxide when you need it, wherever you are.”
For several years, Cohen-Karni and his lab have been developing a technique of growing graphene in a 3D topology, leveraging defects in the material to grow what he calls “fuzzy graphene.” Graphene, which is a form of carbon, is also highly abundant, cheap, and renewable. Cohen-Karni’s method allows graphene to grow away from a surface, rather than along it, creating long, thin, flaky graphene structures that look somewhat like nanoscale pine trees.
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Graphene has an impressive ability to transport electric charge. Building on Cohen-Karni’s fuzzy graphene research, the team found that graphene-based materials with lots of edges, like the ones found at the tips of each fuzzy graphene flake, are highly reactive for synthesizing hydrogen peroxide. So fuzzy graphene, an electrically conductive material with many edges, is the perfect candidate for this new and improved method of hydrogen peroxide generation.
Viswanathan’s research over the last several years has explored the exact properties needed of a catalyst to selectively create hydrogen peroxide from hydrogen and oxygen. Using the Titan, one of the world’s best transmission electron microscopes, the researchers showed that catalytic reactions happen right at the edge of each flake, not on the flat surfaces. The team demonstrated that they can control the kind of catalysis that occurs on fuzzy graphene, selectively creating either hydrogen peroxide or water as they choose by activating the sites at the tips of each flake.
“We can now really controllably make hydrogen peroxide with high selectivity,” says Cohen-Karni. “We are now able to make mostly hydrogen peroxide, and not that much water. Thermodynamics really wants hydrogen and oxygen to form water when catalyzed, so being able to catalyze so selectively, with 94% of the outcome being hydrogen peroxide, means our process is highly novel.”
Other researchers on the paper include MSE Ph.D. students Daniel San Roman (first author) and Raghav Garg; MechE Ph.D. student Dilip Krishnamurthy (co-first author); Director of CMU’s Electron Microscopy & Materials Characterization Facility Noel Nuhfer; Los Alamos National Laboratory’s Hasnain Hafiz; and Rensselaer Polytechnic Institute’s Michael Lamparski and Vincent Meunier.
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