DIDECANOYLPEROXIDE

Didecanoylperoxide is commercially available as white flakes, with a musty odor, insoluble in water, but soluble in organic solvents. 
Didecanoylperoxide is particularly sensitive to temperature rises, contamination, and friction. 
Didecanoylperoxide is a white wet solid. 

CAS Number: 762-12-9
Molecular Formula: C20H38O4
Molecular Weight: 342.51
EINECS Number: 212-092-1

Didecanoylperoxide above a given "Control Temperature" they decompose violently.
Didecanoylperoxide is used as polymerization initiator. 
The deflagration hazard was measured for this organic peroxide. 

The Didecanoylperoxide in powder form showed no pressure rise using 5 g of igniter at 98% purity when using the revised time–pressure test. 
This measurement determined that Didecanoylperoxide is not a deflagration hazard.
Didecanoylperoxide, also known as bis(4-decanoylperoxy)dicarbonate or BPO, is a chemical compound classified as an organic peroxide. 

Didecanoylperoxide is often used as a free-radical initiator in various chemical reactions and polymerization processes.
Organic peroxides like Didecanoylperoxide are compounds that contain a peroxide (-O-O-) functional group and can decompose to produce free radicals, which can initiate chemical reactions.
Didecanoylperoxide is a white, crystalline solid with the chemical formula C20H38O6. 

Didecanoylperoxide is typically used to initiate the polymerization of certain monomers, such as styrene, in the production of polymers and plastics. 
The free radicals generated during the decomposition of Didecanoylperoxide serve as initiators for the crosslinking or curing of polymer chains.
Peroxides, such as Didecanoylperoxide, are good oxidizing agents. Organic compounds can ignite on contact with concentrated peroxides. 

Strongly reduced material such as sulfides, nitrides, and hydrides may react explosively with Didecanoylperoxide. 
There are few chemical classes that do not at least produce heat when mixed with Didecanoylperoxide. 
Many produce explosions or generate gases (toxic and nontoxic). 

Generally, dilute solutions of Didecanoylperoxide (<70%) are safe, but the presence of a catalyst (often a transition metal such as cobalt, iron, manganese, nickel, or vanadium) as an impurity may even then cause rapid decomposition, a buildup of heat, and even an explosion. 
Solutions of Didecanoylperoxide often become explosive when evaporated to dryness or near-dryness.
Didecanoylperoxide is used in the curing process of resin-based composites, such as those used in the manufacturing of surfboards, boat hulls, and composite structures in the marine industry. 

Didecanoylperoxide helps create durable and lightweight composite materials suitable for marine applications.
Didecanoylperoxide is utilized in the polymerization of PMMA, a versatile plastic known for its transparency and impact resistance. 
Didecanoylperoxide is used in various applications, including optical lenses, dental prosthetics, and signage.

Didecanoylperoxide is chosen for applications that require high-temperature resistance, such as in the production of high-temperature gaskets and seals used in automotive and industrial settings.
Didecanoylperoxide is employed in the production of controlled release systems for various applications, including pharmaceuticals, agriculture, and pest control. 
These systems use the gradual release of active ingredients from polymers initiated by Didecanoylperoxide.

Didecanoylperoxide, follow specific regulations regarding the transportation of hazardous materials. 
Secure containers, label them appropriately, and comply with transport regulations to prevent accidents during transit.
Proper disposal of Didecanoylperoxide and materials containing Didecanoylperoxide is essential. 

Consult local environmental regulations and guidelines for the disposal of hazardous waste materials. 
Often, there are specific procedures for disposing of peroxides.
Be aware of the chemical compatibility of Didecanoylperoxide with other substances it may come into contact with, as incompatible materials can lead to hazardous reactions. 

Didecanoylperoxide products have a limited shelf life.
Be mindful of the expiration date and avoid using expired or degraded materials, as they may not function as expected and can be more hazardous.
Didecanoylperoxide should receive proper training and education on the safe handling, storage, and use of the chemical, including emergency response procedures.

Ensure that emergency contact information, including the contact information of Didecanoylperoxide manufacturers and suppliers, is readily available in case of accidents or incidents involving BPO.
Establish clear emergency response procedures and ensure that personnel are trained to respond to accidents, spills, or other incidents involving Didecanoylperoxide. 
Emergency procedures should include actions for controlling fires, containing spills, and providing first aid.

Depending on the specific Didecanoylperoxide and the concentration of vapors or fumes, respiratory protection may be necessary. 
Use appropriate respiratory protection equipment if required, and make sure it is fit-tested and properly maintained.
Clearly label containers and storage areas containing Didecanoylperoxide to indicate its hazardous nature. 

Ensure that labels are in accordance with regulatory requirements and include necessary hazard warnings.
State, and federal regulations that govern the use, storage, and disposal of hazardous chemicals like Didecanoylperoxide. 

Ensure compliance with all applicable regulations and permit requirements.
Periodically inspect containers and storage areas for Didecanoylperoxide to check for leaks, damage, or signs of deterioration. 

Melting point: 40-41 °C
Boiling point: 413.0±28.0 °C(Predicted)
Density: 0.936±0.06 g/cm3(Predicted)
vapor pressure: 0.04Pa at 20℃
Water Solubility: 121.6μg/L at 20.5℃
LogP: 8.38 at 20℃

Didecanoylperoxide should be stored in a cool, well-ventilated area, away from heat sources and open flames. 
Didecanoylperoxide in a tightly closed container to prevent exposure to air and moisture, which can cause decomposition.
Didecanoylperoxide can react with various substances, including reducing agents, strong acids, strong bases, and flammable materials. 

Avoid contact or mixing with these incompatible materials to prevent hazardous reactions.
Didecanoylperoxide is sensitive to heat, light, and shock, which can lead to its decomposition. 
Care should be taken to prevent exposure to high temperatures, direct sunlight, or mechanical impact.

Didecanoylperoxide, ensure that it is properly packaged and labeled according to transportation regulations. 
Use appropriate containers and packaging materials to prevent leaks or spills.
When handling Didecanoylperoxide, wear appropriate PPE, which typically includes safety goggles, chemical-resistant gloves, and protective clothing. 

Didecanoylperoxide use local exhaust ventilation systems or work in a well-ventilated area to minimize inhalation exposure to any vapors or fumes generated during handling.
Be familiar with first-aid procedures for exposure to Didecanoylperoxide. 
In case of contact with the skin, eyes, or ingestion, seek medical attention and provide information about the specific Didecanoylperoxide product involved.

Emergency Response: In the event of a fire or chemical spill involving BPO, follow established emergency response protocols. Fire extinguishing equipment should be suitable for extinguishing fires involving peroxides.

Ensure compliance with local, state, and national regulations and guidelines related to the handling, storage, and disposal of hazardous chemicals, including Didecanoylperoxide.
Employees and personnel handling Didecanoylperoxide should undergo training to understand the potential hazards and safety procedures associated with the chemical.
Establish a proper waste management plan for Didecanoylperoxide and materials containing BPO.

Pay attention to the shelf life and stability of Didecanoylperoxide. 
Expired or degraded materials may pose higher risks.
Maintain accurate records of Didecanoylperoxide use, storage, and disposal to ensure accountability and compliance with safety regulations.

Didecanoylperoxide is used in the production of composite materials, including fiberglass composites and carbon fiber composites. 
Didecanoylperoxide is employed to initiate the curing process of the resin matrix, which binds the fibers together, creating strong and lightweight composite structures used in aerospace, automotive, and construction industries.
Didecanoylperoxide is utilized in the manufacturing of certain medical devices, such as orthopedic implants, where it is involved in the curing of biocompatible polymers used in these applications.

Didecanoylperoxide can be found in the formulation of construction materials like epoxy-based adhesives, coatings, and grouts. 
Didecanoylperoxide aids in the curing and crosslinking of these materials, ensuring their strength and durability in building and infrastructure projects.
In the printing and labeling industry, Didecanoylperoxide is sometimes used in heat-activated inks that require rapid curing during the printing process. 

Didecanoylperoxide is utilized in water treatment processes, such as in the production of water treatment chemicals. 
Didecanoylperoxide plays a role in the polymerization and crosslinking of certain chemicals used for water purification and wastewater treatment.
When working with Didecanoylperoxide, it's essential to keep the compound away from heat sources, sparks, and open flames, as it can be sensitive to ignition and decomposition. 

Be prepared with fire-fighting equipment and spill control measures in case of accidental releases or fires involving Didecanoylperoxide.
Ensure that you are in compliance with local, state, and national regulations related to the handling, transportation, and disposal of hazardous chemicals.

Didecanoylperoxide have been used for many years as sources of free radicals for the initiation of various radical reactions, such as vinyl polymerization. 
Early studies of the decomposition of such Didecanoylperoxide indicated a relatively straightforward mechanism by which the diacyl peroxide broke down by scission of the oxygen-oxygen bond to give acyloxy radicals.

Didecanoylperoxide away from flammable materials and ignition sources. 
Have appropriate fire extinguishing equipment, such as chemical fire extinguishers, on hand, and ensure personnel know how to use them.
Maintain records of safety training and ensure that personnel are up-to-date on safe handling procedures for Didecanoylperoxide.

Keep contact information for the manufacturer or supplier of the Didecanoylperoxide readily available for inquiries, emergency situations, or obtaining additional safety information.
Have spill response kits readily available for quick action in case of a spill. 
These kits should contain absorbent materials, personal protective equipment, and instructions for safely cleaning up spills.

Be mindful of the potential for reactions with other chemicals in workplace. 
Properly segregate BPO from incompatible substances to prevent hazards.
Maintain records of accidents, near-misses, and incidents involving Didecanoylperoxide to assess and improve safety procedures.

Uses Of Didecanoylperoxide:
Didecanoylperoxide is used in the following products: polymers.
Didecanoylperoxide is used for the manufacture of: rubber products and plastic products.
Release to the environment of Didecanoylperoxide can occur from industrial use: as processing aid.

Didecanoylperoxide can be used for the high pressure polymerization of ethylene in autoclaves or tubular reactors. 
Because of the good solubility in mineral oils and aliphatic hydrocarbons the peroxide is easy to handle in the pressure injection system. 
Didecanoylperoxide can also be used as initiator for the suspension polymerization of vinyl chloride in the temperature range between 60°C and 75°C.

Didecanoylperoxide is commonly used to initiate the polymerization of monomers in the production of synthetic polymers and plastics. 
Didecanoylperoxide is particularly effective in processes like radical polymerization, where the formation of free radicals is crucial for the growth of polymer chains. 
This includes the production of materials like acrylics, styrene, and other thermosetting resins.

Didecanoylperoxide is used as a crosslinking agent in the production of cross-linked polyethylene (PEX) pipes and other cross-linked polymer materials. 
This process increases the durability and heat resistance of these materials, making them suitable for applications like plumbing systems.
Didecanoylperoxide is used in the dental industry to initiate the polymerization of dental composites and acrylic materials used for dental restorations, such as dental fillings, crowns, and dentures.

Didecanoylperoxide is employed in the manufacturing of adhesives and sealants to initiate the curing and crosslinking processes. 
This improves the strength and performance of these materials in various applications, including construction and automotive.
In the cosmetics and personal care industry, Didecanoylperoxide can be found in some hair products, such as hair dyes and bleaches, as well as in skin-care products, where it may be used for its polymerization and thickening properties.

Didecanoylperoxide can serve as a source of free radicals in various chemical reactions where radical initiation is required. 
Didecanoylperoxide may be used in the synthesis of specialty organic compounds.
Didecanoylperoxide is used in the production of textiles and synthetic fibers, where it helps initiate polymerization and crosslinking reactions, enhancing the strength and durability of textile materials.

Didecanoylperoxide is widely used to initiate the polymerization of various monomers, such as styrene, methyl methacrylate, and other vinyl-based monomers. 
This process is essential in the production of synthetic polymers and plastics, including polystyrene, acrylics, and polyvinyl chloride (PVC).
Didecanoylperoxide is used to initiate the crosslinking of polymers, enhancing their strength, heat resistance, and other properties. 

Crosslinked polymers are used in various applications, including wire and cable insulation, rubber products, and thermosetting plastics.
Didecanoylperoxide is employed in the production of composite materials, including fiberglass composites, carbon fiber composites, and epoxy resin composites. 
Didecanoylperoxide initiates the curing of the resin matrix, resulting in strong and lightweight materials used in industries such as aerospace, automotive, and construction.

Didecanoylperoxide is used in the dental industry for initiating the polymerization of dental composites and acrylic materials. 
These materials are used in dental restorations, including dental fillings, crowns, and dentures.
Didecanoylperoxide is a key ingredient in the formulation of adhesives and sealants. 

Didecanoylperoxide initiates the curing process, which enhances the strength and performance of these materials. 
They are used in construction, automotive, and industrial applications.
In the pharmaceutical, agricultural, and pest control industries, Didecanoylperoxide is utilized in the production of controlled release systems. 

These systems release active ingredients from polymers gradually, aiding in various applications.
Didecanoylperoxide is found in construction materials such as epoxy-based adhesives, coatings, and grouts. 
Didecanoylperoxide plays a crucial role in the curing and crosslinking of these materials, ensuring their durability in building and infrastructure projects.

In the printing and labeling industry, Didecanoylperoxide is sometimes used in heat-activated inks. 
These inks require rapid curing during the printing process, allowing for quick drying and adhesion to various substrates.
Didecanoylperoxide is used in water treatment processes, including the production of water treatment chemicals. 

Didecanoylperoxide participates in the polymerization and crosslinking of certain chemicals used for water purification and wastewater treatment.
Didecanoylperoxide can be used in the manufacturing of orthopedic implants where it plays a role in the curing of biocompatible polymers used in these medical devices.
In the automotive industry, Didecanoylperoxide is employed in various components like gaskets, seals, and engine mounts, enhancing their durability and heat resistance.

Didecanoylperoxide is used in pharmaceutical applications to initiate the release of drugs from controlled-release systems. 
This ensures a gradual and consistent release of the active pharmaceutical ingredients.
Didecanoylperoxide may be used in the production of high-performance sealing and gasket materials for applications that require resistance to extreme temperatures and pressures in the oil and gas sector.

Didecanoylperoxide is used in UV-curable formulations where it initiates the curing of coatings, inks, and adhesives when exposed to ultraviolet (UV) light. 
This process results in rapid drying and strong bonds.
Didecanoylperoxide can be used in the production of vinyl flooring, where it contributes to the curing of vinyl formulations, making the flooring durable and resilient.

In the manufacture of sporting goods like ski boots, inline skate wheels, and protective padding, Didecanoylperoxide can enhance the properties of materials like thermoplastic elastomers (TPEs).
Didecanoylperoxide is used in marine applications for the production of composite structures in boat building and marine construction, as it aids in the curing of resins, making them suitable for marine environments.

Careful handling and disposal of Didecanoylperoxide and BPO-containing materials are necessary to minimize environmental impact. 
Didecanoylperoxide is a common reagent in research and development labs for initiating chemical reactions, particularly those involving free radical polymerization.
Monitoring the quality and stability of Didecanoylperoxide products is important to ensure their effectiveness and safety in various applications. 

Safety Profile Of Didecanoylperoxide:
Didecanoylperoxide is highly flammable and can ignite when exposed to heat, open flames, or sparks. 
Additionally, Didecanoylperoxide is sensitive to shock and mechanical impact, which can lead to its decomposition and potentially explosive conditions.
Didecanoylperoxide decomposes due to high temperatures or other factors, it can release toxic fumes, including carbon monoxide and other hazardous combustion products. Inhalation of these fumes can be harmful to health.

Didecanoylperoxide can cause skin and eye irritation upon contact. 
Didecanoylperoxide may also be harmful if it comes into contact with mucous membranes.
Didecanoylperoxide is sensitive to heat, light, and mechanical shock. 

These factors can cause Didecanoylperoxide to decompose, potentially resulting in fires or explosions.
Inhalation of Didecanoylperoxide vapors or dust may lead to health effects, such as respiratory irritation, headache, dizziness, and nausea. 
Prolonged or high-level exposure to BPO can have more severe health consequences.

Environmental Impact Of Didecanoylperoxide:
If Didecanoylperoxide is released into the environment, it can have adverse effects on aquatic life and potentially contaminate water sources. 
Didecanoylperoxide is important to manage and dispose of BPO and BPO-containing materials responsibly to minimize environmental harm.
Didecanoylperoxide can react with various substances, including reducing agents, strong acids, strong bases, and flammable materials. 

Synonyms Of Didecanoylperoxide:
DECANOYL PEROXIDE
Peroxide, bis(1-oxodecyl)
762-12-9
decanoic peroxyanhydride
5YFN3ID35B
Bisdecanoyl peroxide
didecanoyl peroxide
decanoyl decaneperoxoate
UNII-5YFN3ID35B
caproyl peroxide
EINECS 212-092-1
DECANOX F
PERKADOX SE 10
EC 212-092-1
SCHEMBL23375
DTXSID0061084
XJOBOFWTZOKMOH-UHFFFAOYSA-N
Q27263048