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2,2,3,4,4,4-hexafluorobutyl Methacrylate


Properties
Product Name 2,2,3,4,4,4-Hexafluorobutyl methacrylate
Cas Number 54060-88-9
Formula C8H8F6O2
Molar Mass 250.14
Boiling Point 61°C (at 8 mmHg)
Density 1.409 g/mL
Refractive Index 1.374
Flash Point 52°C
Appearance Colorless liquid
Viscosity 1.3 cP at 20°C
Solubility In Water Not soluble
Vapor Pressure 11.5 mmHg at 25°C
Storage Temperature Refrigerate
Stability Stable under recommended storage conditions
FAQ

What are the main applications of 2,2,3,4,4,4-Hexafluorobutyl Methacrylate?

2,2,3,4,4,4 - Hexafluorobutyl Methacrylate is a fluorinated monomer with several important applications.Hexafluorobutyl methacrylate, also known as 2,2,3,4,4,4- Hexafluorobutyl methacrylate, is a monomer fluorinated with many important applications.
One of the key areas is in the production of high - performance coatings.The production of high-performance coatings is a key area. These coatings are highly resistant to chemicals, water, and abrasion.These coatings are highly resistant against chemicals, water and abrasion. In the automotive industry, for example, they can be used to create top - coat finishes.They can be used in the automotive industry to create top-coat finishes. The fluorinated nature of the monomer imparts hydrophobic and oleophobic properties to the coating.The fluorinated monomer gives the coating hydrophobic and oil-phobic properties. This means that water, oil, and other contaminants have a hard time adhering to the surface.Water, oil and other contaminants will have a difficult time adhering to this surface. As a result, cars coated with materials containing 2,2,3,4,4,4 - Hexafluorobutyl Methacrylate require less frequent washing and are more resistant to environmental damage like acid rain and road salt.Cars coated with 2,2,3,4,4,4- Hexafluorobutyl Methacrylate are less likely to require frequent washing, and they are more resistant against environmental damage such as acid rain and road sal.

In the field of electronics, it is used in the manufacturing of protective films.In the electronics industry, it is used to manufacture protective films. Electronic devices such as smartphones and tablets are often exposed to various environmental factors.Electronic devices like smartphones and tablets are frequently exposed to different environmental factors. Films made from this monomer can provide excellent scratch resistance, while also protecting the device from moisture.This monomer is used to make films that are scratch resistant and protect the device from moisture. This helps to extend the lifespan of the electronic components and maintain the functionality of the device.This can help to prolong the life of electronic components and maintain functionality of the device.

It also has applications in the textile industry.It is also used in the textile industry. When incorporated into textile finishes, it can make fabrics water - repellent, stain - resistant, and soil - release.It can be used to make textiles water-repellent, stain-resistant, and soil-release when incorporated into textile finishes. For outdoor clothing, this property is crucial as it allows the fabric to keep the wearer dry in wet conditions.This property is essential for outdoor clothing as it keeps the wearer dry even in wet conditions. Additionally, the treated fabrics are easier to clean, as dirt and stains do not penetrate deeply into the fabric fibers.The treated fabrics are also easier to clean because dirt and stains don't penetrate deep into the fabric fibers.

In the area of biomedical applications, materials containing this monomer can be used to create biocompatible coatings.Materials containing this monomer are used to create biocompatible materials in biomedical applications. These coatings can be applied to medical devices such as catheters.These coatings can also be applied to medical equipment such as catheters. The fluorinated coating helps to reduce the adhesion of proteins and cells to the surface of the device, minimizing the risk of thrombosis and infection.The fluorinated surface reduces the adhesion between cells and proteins to the surface, reducing the risk of infection and thrombosis. This is because the smooth and non - adhesive surface created by the fluorinated material prevents the attachment and growth of potentially harmful biological substances.The fluorinated material creates a non-adhesive surface that prevents the attachment of harmful biological substances.

Finally, in the production of polymers for optical applications, 2,2,3,4,4,4 - Hexafluorobutyl Methacrylate can be used to modify the refractive index.In the production of polymers used in optical applications, the 2,2,3,4,4,4- Hexafluorobutyl methacrylate is a useful way to modify the index of refraction. This is useful in the manufacturing of lenses, optical fibers, and other optical components, where precise control of optical properties is essential for optimal performance.This is useful when manufacturing lenses, optical fibres, and other components where precise control of optical property is necessary for optimal performance.

What are the safety precautions when handling this product?

When handling this product, several important safety precautions should be followed.Several important safety precautions must be observed when handling this product. First, always read and understand the product manual thoroughly before use.Before using the product, it is important to read and understand its manual. The manual contains crucial information about the proper handling, features, and potential hazards associated with the product.The manual contains important information about how to use the product, its features and any potential hazards. This knowledge will enable you to operate it correctly and avoid any unforeseen risks.This will allow you to use the product correctly and avoid any unforeseeable risks.
Second, ensure that you are in a suitable environment.Secondly, make sure you are in an appropriate environment. The area where the product is being handled should be clean, dry, and well - ventilated.The area where you are handling the product should be clean, well-ventilated, and dry. A dirty or wet environment can damage the product and may also pose electrical risks if the product is electrical.A dirty or damp environment can damage a product and also pose electrical hazards if it is electrical. Inadequate ventilation can cause overheating, especially for products that generate heat during operation, which could lead to component failures or even fires.Inadequate ventilation may cause overheating in products that generate heat when they are used. This can lead to component failures and even fires.

If the product is electrical, check the power cords regularly.Check the power cords of electrical products regularly. Look for any signs of fraying, cuts, or exposed wires.Check for signs of fraying or cuts. Using a damaged power cord can result in electric shock or short - circuits.Electric shocks or short circuits can occur when using a damaged power cable. When plugging or unplugging the product, do it gently and hold the plug itself, not the cord.When plugging in or unplugging a product, hold the plug, not the cord. Avoid overloading electrical sockets by not plugging in too many high - wattage devices simultaneously.Avoid overloading electrical outlets by not plugging too many high-wattage devices at once.

For products with moving parts, keep your hands, hair, and loose clothing away from them.Keep your hair and loose clothing out of reach from products with moving parts. Moving parts can easily catch onto these items, pulling them in and potentially causing serious injury.These items can be easily caught by moving parts, causing them to be pulled in and possibly causing serious injuries. If the product requires maintenance or cleaning while it is running, make sure to follow the specific procedures outlined in the manual to avoid contact with the moving components.If you need to perform maintenance or clean the product while it is in operation, follow the instructions in the manual to prevent contact with moving components.

When lifting the product, use proper lifting techniques.Use proper lifting techniques when lifting the product. Bend your knees, keep your back straight, and lift with your legs rather than your back.Lift with your legs, not your back. Bend your knees and keep your back straight. This helps prevent back injuries, especially if the product is heavy.This will help prevent back injuries, particularly if the product you are lifting is heavy. If the product is too heavy to lift alone, seek assistance or use appropriate lifting equipment.If the product is too large to lift by yourself, ask for help or use lifting equipment.

In case of chemical - containing products, wear the necessary protective gear.Wear the appropriate protective gear when using products containing chemicals. This may include gloves, goggles, and a mask, depending on the nature of the chemicals.Depending on the chemical, this may include gloves, goggles and a face mask. Avoid direct skin contact, inhalation, or ingestion of these substances.Avoid direct skin contact or ingestion. Also, store chemical - based products in a cool, dry place, away from heat sources and other incompatible materials.Store chemical-based products in a dry, cool place away from heat sources.

Finally, be aware of the product's limitations.Be aware of the limitations of the product. Do not attempt to use it for purposes other than what it is designed for.Do not use it for anything other than the intended purpose. Over - stressing the product beyond its rated capacity can lead to malfunctions, breakdowns, and safety hazards.Over-stressing the product can cause malfunctions, breakdowns and safety hazards. If you notice any abnormal behavior, such as strange noises, odors, or excessive heat, immediately stop using the product and seek professional help for diagnosis and repair.If you notice any abnormal behaviors, such as strange sounds, odors or excessive heat, stop using the product immediately and seek professional assistance for diagnosis and repair.

What is the purity of 2,2,3,4,4,4-Hexafluorobutyl Methacrylate?

The purity of 2,2,3,4,4,4 - Hexafluorobutyl Methacrylate can vary significantly depending on its source, manufacturing process, and subsequent purification steps.Purity of 2,2,3,4,4,4- Hexafluorobutyl Methacrylate varies significantly depending on its origin, manufacturing process and subsequent purification.
In general, for research - grade chemicals, a relatively high purity is expected.In general, high purity is expected for research-grade chemicals. Manufacturers often strive to produce this compound with a purity of at least 95% or higher.Most manufacturers strive to produce this chemical with a purity level of 95% or more. High - purity 2,2,3,4,4,4 - Hexafluorobutyl Methacrylate is crucial in applications where impurities could interfere with chemical reactions or product performance.In applications where impurities can interfere with chemical reactions and product performance, high-purity 2,2,3,4,4,4-hexafluorobutyl methacrylate is essential.

For example, in polymer synthesis, if the monomer has low purity, it can lead to unexpected side - reactions during polymerization.In polymer synthesis for example, if a monomer is not pure enough, it may cause unexpected side-reactions during polymerization. Impurities might act as chain - transfer agents or initiators, altering the molecular weight and structure of the resulting polymer.Impurities can act as initiators or chain - transfer agents, altering the structure and molecular weight of the polymer. In coatings applications, impurities in the 2,2,3,4,4,4 - Hexafluorobutyl Methacrylate can affect the film - forming properties, such as adhesion, hardness, and chemical resistance.Impurities in 2,2,3,4,4,4- Hexafluorobutyl methacrylate can alter the film-forming properties of coatings, such as adhesion and chemical resistance.

Commercial products may have different purity levels based on their intended use.Purity levels may vary depending on the intended use of commercial products. Some industrial - grade versions might have a purity in the range of 90 - 95%.Some industrial-grade versions may have a purity between 90 and 95%. These can be suitable for applications where the presence of minor impurities does not severely impact the overall process or the final product quality.These are suitable for applications in which the presence of minor contaminants does not have a significant impact on the process or final product quality. However, for more sensitive applications like in the electronics industry for manufacturing optical polymers or in medical device coatings, a much higher purity close to 99% or even higher may be required.For more sensitive applications, such as in the electronics industry, where optical polymers are manufactured, or in medical device coatings requiring a higher purity, it may be necessary to achieve a purity of 99% or higher.

The purity is determined through various analytical techniques.Purity is determined by using various analytical techniques. Gas chromatography (GC) is a common method to separate and quantify the amount of 2,2,3,4,4,4 - Hexafluorobutyl Methacrylate and its impurities.Gas chromatography is a method that is commonly used to separate and measure the amount of 2,2,3,4,4,4 – Hexafluorobutyl methacrylate (HFBM) and its impurities. High - performance liquid chromatography (HPLC) can also be used, especially when dealing with non - volatile impurities.HPLC is also a good option, especially for non-volatile impurities. Nuclear magnetic resonance (NMR) spectroscopy can provide information about the chemical structure and the presence of any contaminants through the analysis of the chemical shifts and coupling constants.Nuclear magnetic resonance spectroscopy (NMR) can provide information on the chemical structure of contaminants and their presence through the analysis chemical shifts and coupling coefficients.

In conclusion, the purity of 2,2,3,4,4,4 - Hexafluorobutyl Methacrylate is a critical parameter that depends on its end - use.In conclusion, the purity level of 2,2,3,4,4,4- Hexafluorobutyl methacrylate is an important parameter that depends on the end-use. While research and high - end applications demand very high purity, some industrial applications can tolerate slightly lower purity levels, but still within a range that ensures the functionality of the compound in the relevant processes.While research and high-end applications require very high purity, certain industrial applications can tolerate slightly less purity as long as it is within a range ensuring the compound's functionality in the relevant processes.

What is the melting point of this compound?

To determine the melting point of a compound, several factors need to be considered.To determine the melting temperature of a compound several factors must be taken into consideration. Firstly, the nature of the compound plays a crucial role.The first factor to consider is the composition of the compound. Different types of compounds have characteristic melting point ranges.Different types of compounds are characterized by different melting points.
Ionic compounds, for example, generally have high melting points.Ionic compounds have high melting points. This is because they consist of positively and negatively charged ions held together by strong electrostatic forces in a crystal lattice.This is because the ions are held together by strong electric forces in a crystal structure. To break these ionic bonds and convert the solid into a liquid, a significant amount of energy is required.It takes a lot of energy to break these ionic bond and turn the solid into liquid. Salts like sodium chloride have melting points well above room temperature, with sodium chloride melting at around 801 degrees Celsius.Salts such as sodium chloride melt at temperatures well above room temperature. Sodium chloride melts at about 801 degrees Celsius.

Covalent compounds can have a wide range of melting points.Covalent compounds have a range of melting temperatures. Non - polar covalent compounds with small molecules, such as methane (CH4), have very low melting points.Small molecules such as methane, a non-polar covalent compound, have extremely low melting points. Methane is a gas at room temperature and melts at - 182.5 degrees Celsius.Methane melts at -182.5 degrees Celsius at room temperature. The weak van der Waals forces between non - polar molecules are easily overcome, resulting in low melting points.Low melting points are due to the weak van der Waals force between non-polar molecules.

On the other hand, polar covalent compounds can have relatively higher melting points compared to non - polar ones of similar molecular size.Compared to non-polar compounds of similar size, polar covalents can have higher melting points. This is due to the presence of dipole - dipole interactions.This is due the presence of dipole-dipole interactions. For instance, water (H2O) has a melting point of 0 degrees Celsius.Water (H2O), for example, has a melting temperature of 0 degrees Celsius. The hydrogen bonding in water, a special type of dipole - dipole interaction, contributes to this relatively higher melting point compared to non - polar compounds of similar molar mass.This is due to the hydrogen bonding, a type of dipole-dipole interaction, in water.

Macromolecular covalent compounds, like diamond (a form of carbon) or quartz (SiO2), have extremely high melting points.The melting points of macromolecular covalent compounds like diamond (a type of carbon) and quartz (SiO2) are extremely high. In diamond, each carbon atom is covalently bonded to four other carbon atoms in a three - dimensional network.Each carbon atom in diamond is covalently bound to four other carbons atoms, forming a three-dimensional network. The extensive covalent bonding throughout the structure requires a vast amount of energy to break, and diamond melts at approximately 3550 degrees Celsius.Diamond melts at 3550 degrees Celsius due to the extensive covalent bonding.

To experimentally determine the melting point of a compound, a melting point apparatus is commonly used.A melting point apparatus can be used to experimentally determine the melting temperature of a compound. A small sample of the compound is placed in a capillary tube, which is then inserted into the apparatus.The melting point apparatus is used to determine the melting point of a compound by placing a small sample in a capillary. The temperature of the apparatus is gradually increased, and the temperature at which the compound starts to melt and becomes completely liquid is recorded as the melting point.The apparatus temperature is increased gradually, and the melting point is the temperature at which a compound begins to melt and becomes liquid. A pure compound typically has a sharp melting point range, usually within 1 - 2 degrees Celsius.A pure compound usually has a sharp range of melting points, usually between 1 and 2 degrees Celsius. Impurities in the compound can lower the melting point and broaden the melting point range.Impurities can lower the melting temperature and increase the melting range.

In conclusion, without knowing the specific compound in question, it's impossible to give an exact melting point.It is impossible to determine the melting point of a compound without knowing its specific composition. But by understanding the general principles related to the structure and bonding of different types of compounds, one can make an educated guess about whether the melting point is likely to be high, low, or in a certain intermediate range.By understanding the general principles relating to the structure and bonds of different types compounds, one can make a educated guess as to whether the melting point will be high, low or in an intermediate range.

How is 2,2,3,4,4,4-Hexafluorobutyl Methacrylate stored?

2%2C2%2C3%2C4%2C4%2C4 - Hexafluorobutyl Methacrylate is a type of chemical compound. When it comes to its storage, several key factors need to be considered.When it comes time to store this chemical, there are several factors to consider.
First, it should be stored in a cool and well - ventilated area.It should be kept in a well-ventilated, cool area. High temperatures can accelerate chemical reactions, potentially leading to decomposition or polymerization of the compound.High temperatures can accelerate a chemical reaction, which could lead to the decomposition or polymerization. A storage temperature in the range of typically 2 - 8 degrees Celsius is often recommended for many methacrylate - based substances.Many methacrylate-based substances are stored at temperatures between 2 and 8 degrees Celsius. This helps maintain its chemical stability over time.This will help maintain its chemical stability.

Second, it must be stored away from sources of ignition.Second, it should be stored away from ignition sources. 2%2C2%2C3%2C4%2C4%2C4 - Hexafluorobutyl Methacrylate is likely to be flammable, like many organic compounds. Any open flames, sparks from electrical equipment, or hot surfaces in the storage area can pose a significant fire hazard.Open flames, sparks or hot surfaces can cause a fire.

Third, it should be kept in a tightly sealed container.Third, it must be stored in a tightly-sealed container. Exposure to air can cause oxidation or reaction with moisture in the air.Air exposure can cause oxidation and/or reaction with the moisture in air. Moisture can initiate hydrolysis reactions in some methacrylate compounds, which can change their chemical properties.Moisture may initiate hydrolysis reactions that can alter the chemical properties of some methacrylate substances. A well - sealed container also prevents the escape of volatile vapors, which may be harmful if inhaled.A tightly sealed container prevents the escape and inhalation of volatile vapors.

Fourth, the storage area should be protected from direct sunlight.Fourth, the storage area must be shielded from direct sunlight. Ultraviolet light from sunlight can act as an initiator for certain photochemical reactions.Certain photochemical reactions can be triggered by ultraviolet light from sunlight. These reactions can lead to changes in the structure and properties of 2%2C2%2C3%2C4%2C4%2C4 - Hexafluorobutyl Methacrylate, such as cross - linking or degradation.

Fifth, it is important to store this compound separately from incompatible substances.It is important to store the compound away from other substances that are incompatible. For example, strong oxidizing agents or acids may react violently with methacrylate compounds.Strong oxidizing agents and acids, for example, may react violently when used with methacrylate. Chemical compatibility charts should be consulted to ensure that no potentially reactive substances are stored in close proximity.Chemical compatibility charts can be used to ensure that potentially reactive substances are not stored close together.

Finally, proper labeling of the storage container is crucial.Labeling the container is also important. The label should clearly indicate the name of the compound, any hazard warnings such as flammability or toxicity, and the date of storage.Labels should clearly state the name of the compound and any warnings about flammability, toxicity or other hazards. They should also include the date of storage. This not only helps in proper identification but also in tracking the age of the stored material, as older samples may need to be tested for quality before use.This helps to identify the material and also track its age, as older samples might need to be tested before use. By following these storage guidelines, the integrity and safety of 2%2C2%2C3%2C4%2C4%2C4 - Hexafluorobutyl Methacrylate can be maintained.