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Bio-isobutyl Acrylate


Properties
Product Name Bio-Isobutyl acrylate
Cas Number 106-63-8
Formula C7H12O2
Molar Mass 128.17 g/mol
Boiling Point 155°C
Density 0.887 g/cm³
Flash Point 46°C
Refractive Index 1.415
Vapor Pressure 3.7 mmHg at 25°C
Solubility In Water Slightly soluble
Appearance Colorless liquid
Odor Acrid
Autoignition Temperature 320°C
Viscosity 0.7 cP at 20°C
FAQ

What is the chemical structure of Bio-Isobutyl acrylate?

Bio - Isobutyl acrylate is an acrylate - type compound.Bio-isobutyl-acrylate is a type of acrylate compound. Its chemical structure can be understood by breaking down the components of its name.You can understand its chemical structure by breaking down its name.
First, the acrylate part indicates the presence of an acrylate group.The acrylate part is the first indication of the presence of the acrylate group. The acrylate group has the general formula CH2=CH - COO - R, where R represents an organic group attached to the carboxylate oxygen.The acrylate group is represented by the general formula CH2=CH-COO-R, where R is an organic group attached the carboxylate oxygen. In this case, the R group is an isobutyl group.In this case, R is an isobutyl.

The isobutyl group is a branched - chain alkyl group.The isobutyl alkyl group is a branched-chain alkyl group. It has the formula - CH2 - CH(CH3)2.It has the formula: -CH2 -CH(CH3)2. The carbon atom of the isobutyl group's terminal methylene (- CH2 - ) is bonded to the oxygen atom of the carboxylate group in the acrylate structure.The terminal methylene of the isobutyl (- CH2 -- ) group is bonded with the oxygen atom in the carboxylate group of the acrylate.

Combining these parts, the chemical structure of bio - isobutyl acrylate is CH2=CH - COO - CH2 - CH(CH3)2.Combining these parts gives us CH2=CH-COO-CH2 -CH(CH3)2.

The double - bond in the acrylate part, between the two carbon atoms (CH2=CH -), is a site of high reactivity.The double-bond in the acrylate portion, between the two carbons atoms (CH2=CH-), is an area of high reactivity. This double - bond can participate in various polymerization reactions.This double-bond can be involved in different polymerization reactions. Through addition polymerization, multiple bio - isobutyl acrylate monomers can react with each other.Multiple bio - isobutylacrylate monomers react with each through addition polymerization. The double - bond breaks, and new carbon - carbon single bonds are formed, creating long - chain polymers.The double – bond breaks and new carbon-carbon single bonds are created, creating long-chain polymers.

The isobutyl group attached to the oxygen of the carboxylate part imparts certain physical and chemical properties to the molecule.The isobutyl groups attached to the carboxylate part of the molecule impart certain physical and chemical characteristics to the molecule. The branched structure of the isobutyl group affects the solubility, viscosity, and glass - transition temperature of the compound.The branched structure affects the solubility of the compound, its viscosity and glass-transition temperature. For example, compared to a linear alkyl - acrylate, the branched isobutyl group can reduce the tendency of the molecules to pack closely together, which may result in a lower glass - transition temperature and different solubility characteristics in various solvents.The branched structure of the isobutyl groups can reduce the tendency for molecules to pack tightly together. This may result in lower glass-transition temperatures and different solubility properties in various solvents. Overall, the unique chemical structure of bio - isobutyl acrylate makes it useful in applications such as coatings, adhesives, and polymer - based materials where its reactivity and physical properties can be exploited.The unique chemical structure of the bio - isobutyl-acrylate allows it to be used in coatings, adhesives and polymer-based materials, where its reactivity, and physical properties, can be exploited.

What are the main applications of Bio-Isobutyl acrylate?

Bio - Isobutyl acrylate has several important applications.Bio-Isobutyl Acrylate has many important applications.
One of its key uses is in the field of coatings.Coatings are one of its main uses. It can be incorporated into coating formulations to enhance various properties.It can be added to coating formulations to improve various properties. For example, in automotive coatings, it contributes to improving the hardness and abrasion resistance of the paint.In automotive coatings it can improve the hardness and resistance to abrasion of the paint. This helps the car's finish to withstand the daily wear and tear, such as scratches from road debris and minor impacts.This helps the finish of the car to withstand daily wear and tear such as scratches caused by road debris and minor impact. In industrial coatings, it can enhance the durability of coatings on machinery and equipment, protecting them from corrosion and mechanical damage.In industrial coatings it can increase the durability of coatings protecting machinery and equipment from corrosion and mechanical damages.

In the adhesives industry, bio - isobutyl acrylate plays a significant role.Bio - isobutylacrylate is a key ingredient in the adhesives industry. It is used to formulate adhesives with good adhesion properties.It is used in the formulation of adhesives that have good adhesion. These adhesives can be applied in a variety of settings, from bonding materials in the manufacturing of consumer products like electronics and furniture to use in construction for adhering different building materials together.These adhesives are used in many different settings, including the manufacture of consumer goods like electronics and furniture or in construction to adhere different building materials. The acrylate's properties allow for strong and long - lasting bonds, ensuring the integrity of the assembled products.The properties of acrylate allow for strong, long-lasting bonds that ensure the integrity and quality of the assembled product.

It is also utilized in the production of polymers.It is also used in the production polymers. When copolymerized with other monomers, it can modify the properties of the resulting polymer.It can be copolymerized to modify the properties of a polymer. For instance, it can adjust the glass transition temperature of the polymer, which is crucial for determining its physical state and performance under different temperature conditions.It can, for example, adjust the polymer's glass transition temperature, which is critical to its physical state and performance at different temperatures. This makes it possible to tailor - make polymers for specific applications, whether it's for flexible plastics used in packaging or more rigid polymers for structural components.This allows for the tailor-making of polymers to suit specific applications.

In the area of inks, bio - isobutyl acrylate is used to improve the performance of inkjet inks and printing inks.Bio - isobutylacrylate is used in the ink industry to improve the performance and durability of inkjet and printing inks. It can enhance the drying speed of the ink, reducing the risk of smudging.It can increase the drying speed of inks, reducing the risk for smudging. Additionally, it helps in achieving better color fastness and adhesion to different substrates, such as paper, fabric, and plastics.It also helps to achieve better color fastness, adhesion, and adhesion on different substrates such as paper and fabric. This ensures high - quality printing results, whether it's for commercial printing, textile printing, or digital printing applications.This ensures high-quality printing results for commercial printing, digital printing, and textile printing.

Furthermore, in the medical field, although more research is ongoing, its potential applications are emerging.In the medical field as well, more research is being done, but its potential applications are beginning to emerge. It could potentially be used in the development of certain medical devices or drug delivery systems due to its chemical properties that can be tailored to interact with biological systems in a controlled manner.It could be used to develop certain medical devices or drug-delivery systems because its chemical properties can be tailored to interact in a controlled way with biological systems. However, strict safety and biocompatibility tests need to be conducted before widespread medical use.Before widespread medical use, however, strict safety and compatibility tests must be conducted. Overall, bio - isobutyl acrylate has diverse applications across multiple industries, driving innovation and improving the performance of various products.Bio - isobutylacrylate has a wide range of applications in multiple industries. It drives innovation and improves the performance of many products.

Is Bio-Isobutyl acrylate safe for use?

Bio - Isobutyl acrylate is a chemical compound.Bio - Isobutyl Acrylate is a chemical compound. When considering its safety for use, several aspects need to be evaluated.In order to evaluate its safety, it is important to consider several factors.
In terms of acute toxicity, studies on laboratory animals have shown that high - dose exposure to isobutyl acrylate (the non - bio - labeled form, but with similar chemical properties) can cause harmful effects.Studies on laboratory animals have shown, in terms of acute toxicity that high-dose exposure to isobutyl-acrylate (the form without bio-labeling, but with chemical properties similar) can cause harmful side effects. Inhalation of high concentrations may irritate the respiratory tract, leading to symptoms like coughing, shortness of breath, and potentially more serious lung damage.Inhalation of high levels of isobutyl acrylate can cause respiratory irritation, resulting in symptoms such as coughing, shortness-of-breath, and even more serious lung damage. Skin contact can also result in irritation and may cause allergic reactions in some individuals.Contact with the skin can also cause irritation and allergic reactions. However, in normal industrial or consumer use scenarios where proper safety measures are in place, the risk of acute high - dose exposure is significantly reduced.In normal industrial or consumer scenarios, where safety measures are in effect, the risk of an acute high-dose exposure is greatly reduced.

Regarding chronic effects, long - term exposure to isobutyl acrylate has been a subject of concern.Concerns have been raised about chronic effects of isobutylacrylate. Some research indicates potential carcinogenic effects, although the evidence is not conclusive.Despite the lack of conclusive evidence, some research has indicated that isobutyl acrylate may cause cancer. If workers are repeatedly exposed to the compound over years without adequate protection, there could be an increased risk of developing certain types of cancers.Workers who are exposed to the compound repeatedly over many years without adequate protection could be at increased risk of developing cancer.

For environmental safety, when bio - isobutyl acrylate is released into the environment, it may pose risks to aquatic life.Bio-isobutylacrylate can pose risks to aquatic animals, if released into the environment. It can be toxic to fish, invertebrates, and other organisms in water bodies.It can be toxic for fish, invertebrates and other organisms living in water bodies. The biodegradability of bio - isobutyl acrylate is an important factor.Biodegradability is a key factor. If it degrades relatively quickly in the environment, the long - term environmental impact may be lessened.The long-term environmental impact can be reduced if it degrades quickly in the environment.

In consumer products, its use is often restricted.In consumer products its use is often limited. Regulatory bodies around the world set limits on the amount of isobutyl acrylate that can be present in various products.Around the world, regulatory bodies set limits for the amount of isobutyl-acrylate that may be present in different products. For example, in cosmetics, only very low levels are allowed to ensure consumer safety.In cosmetics, for example, only very low levels can be used to ensure consumer safety.

Overall, while bio - isobutyl acrylate can be used, strict safety precautions must be adhered to.Bio - isobutyl Acrylate can be used in general, but strict safety precautions should be observed. In industrial settings, workers should use appropriate personal protective equipment such as gloves, goggles, and respiratory protection.Workers in industrial settings should wear appropriate personal protective gear such as goggles, gloves, and respiratory protection. In the development and use of consumer products, manufacturers need to ensure compliance with safety regulations.Manufacturers must ensure that safety regulations are followed in the development and use consumer products. When managed properly, the risks associated with bio - isobutyl acrylate can be minimized, but its potential hazards should not be overlooked.The risks associated with bio-isobutylacrylate can be reduced when managed properly. However, its potential hazards shouldn't be overlooked.

How is Bio-Isobutyl acrylate produced?

Bio - Isobutyl acrylate is typically produced through a series of chemical processes.Bio-isobutylacrylate is usually produced by a series chemical processes. One common route involves starting with bio - based feedstocks.One common route is to start with bio-based feedstocks.
First, bio - ethanol can be obtained from the fermentation of biomass such as corn, sugarcane, or other renewable sources.Bio - ethanol is produced by fermenting biomass, such as corn, cane sugar, or other renewable sources. This bio - ethanol is then dehydrated to produce ethylene.This bio-ethanol is then dehydrated in order to produce ethylene. The dehydration reaction usually takes place over a suitable catalyst, like a solid acid catalyst such as zeolites.The dehydration reaction is usually carried out over a suitable catalyst, such as solid acid catalysts like zeolites.

Next, the ethylene is reacted with carbon monoxide and hydrogen in the presence of a catalyst in a process known as hydroformylation.Hydroformylation is the next step, in which ethylene reacts with hydrogen and carbon monoxide in the presence a catalyst. This reaction results in the formation of propionaldehyde.This reaction produces propionaldehyde. The catalyst used is often a transition - metal complex, like a rhodium - based catalyst.The catalyst is usually a transition-metal complex, such as a rhodium-based catalyst.

Propionaldehyde is then further reacted with formaldehyde in a reaction called aldol condensation.The reaction between propionaldehyde and formaldehyde, called aldol condensing, is then carried out. This step forms methacrolein.This step produces methacrolein. The aldol condensation reaction is typically carried out under basic conditions.The aldol reaction is usually carried out in basic conditions.

Finally, methacrolein is oxidized to methacrylic acid and then esterified with isobutanol to produce bio - isobutyl acrylate.Finaly, methacrolein can be oxidized into methacrylic acids and esterified with bio-isobutyl alcohol to produce bio-isobutyl acrylicate. The oxidation of methacrolein can be achieved using air or oxygen in the presence of a suitable oxidation catalyst.In the presence of an oxidation catalyser, methacrolein is oxidized using oxygen or air. The esterification reaction between methacrylic acid and isobutanol is usually catalyzed by an acid catalyst, such as sulfuric acid or a solid - acid catalyst.A solid-acid catalyst or sulfuric acid is used to catalyze the esterification of methacrylic and isobutanol. This multi - step process allows for the production of bio - isobutyl acrylate from renewable bio - based starting materials, reducing the reliance on fossil - fuel - derived feedstocks and contributing to a more sustainable chemical production pathway.This multi-step process allows the production of bio-isobutyl-acrylate from renewable bio-based starting materials. It reduces the reliance on fossil-fuel derived feedstocks, and contributes to a more sustainable chemical manufacturing pathway.

What are the properties of Bio-Isobutyl acrylate?

Bio - Isobutyl acrylate is a derivative of acrylate with certain properties.Bio - Isobutyl Acrylate is a derivative with certain properties.
In terms of physical properties, it is likely to be a colorless to light - colored liquid.Physically, it will be a liquid that is colorless or light-colored. It has a characteristic odor, which is common among acrylate - based compounds.It has a characteristic smell, which is common to acrylate-based compounds. The boiling point of bio - isobutyl acrylate is determined by its molecular structure and intermolecular forces.The molecular structure of bio-isobutyl isobutyl isobutyl isobutyl isobutyl isobutyl isobutyl and the intermolecular force determines its boiling point. Generally, acrylate esters have boiling points in a range that allows them to be volatile under appropriate conditions.Generally, acrylate ester boiling points are in a range which allows them to be volatile when the conditions are right. Its density is another important physical property.Another important physical property is its density. The density is typically such that it can be easily separated from other substances with significantly different densities during processing operations.Its density is usually such that it can easily be separated from other substances of significantly different densities when processing operations.

Regarding chemical properties, bio - isobutyl acrylate contains a reactive double bond in its acrylate group.In terms of chemical properties, the acrylate group in bio-isobutylacrylate contains a double bond that is reactive. This double bond makes it highly reactive towards addition reactions.This double bond makes the acrylate highly reactive to addition reactions. It can participate in polymerization reactions, which is a crucial property.It is able to participate in polymerization, which is an important property. Polymerization can occur through various mechanisms, such as free - radical polymerization.Polymerization can be achieved by various mechanisms, including free-radical polymerization. When polymerized, it can form polymers with different molecular weights and architectures depending on the reaction conditions.Depending on the reaction conditions, it can produce polymers of different molecular masses and architectures. These polymers may have applications in areas like coatings, adhesives, and plastics.These polymers can be used in coatings, plastics, and adhesives.

The bio - prefix indicates that it may have some origin or characteristics related to biological processes.The bio-prefix indicates that the product may have biological origins or characteristics. It could potentially be derived from renewable resources, which gives it an advantage in terms of sustainability compared to some petrochemical - based counterparts.It may be derived from renewable sources, giving it an advantage when compared to petrochemical-based counterparts. This may also influence its biodegradability to some extent.This could also affect its biodegradability in some way. If it is indeed derived from biological sources, it might be more amenable to degradation by certain microorganisms in the environment.If it is derived from biological sources it may be more susceptible to degradation by certain microorganisms.

In addition, its solubility properties are important.Its solubility is also important. It may have some solubility in organic solvents, which is useful for formulating solutions in industrial applications.It is soluble in organic solvents which can be useful when formulating industrial solutions. However, its solubility in water is usually limited due to the hydrophobic nature of the isobutyl group attached to the acrylate moiety.Its solubility in liquid water is usually limited by the hydrophobic nature the isobutyl moiety attached to the acrylate group. This hydrophobicity also affects its interaction with other substances, such as its ability to repel water when used in coatings, which can enhance the water - resistance of the coated materials.This hydrophobicity can also affect its interaction with other substances. For example, its ability to repel moisture when used in coatings can enhance the water-resistance of coated materials. Overall, the properties of bio - isobutyl acrylate make it a valuable compound in different industrial sectors with an increasing focus on sustainable and environmentally friendly materials.Bio - isobutylacrylate's properties make it a valuable material in many industrial sectors, especially with the increasing focus on sustainable materials.