CAS 13674 - 84 - 5 refers to a specific chemical compound. As a reliable supplier of this compound, I am here to share detailed information about its chemical properties, which can help you better understand its characteristics and potential applications.
1. Basic Information
CAS 13674 - 84 - 5 is a chemical with a unique molecular structure that endows it with specific chemical and physical properties. This compound is often used in various industrial fields due to its special features.
2. Chemical Structure and Composition
To understand the chemical properties of CAS 13674 - 84 - 5, we first need to look at its chemical structure. The structure of a chemical compound determines its reactivity and other chemical behaviors. Although the exact structure of CAS 13674 - 84 - 5 may be complex, it contains certain functional groups that play crucial roles in its chemical reactions.
3. Reactivity
3.1 Reactivity with Acids and Bases
CAS 13674 - 84 - 5 may show different reactivities when exposed to acids and bases. In an acidic environment, it may undergo protonation reactions if there are suitable basic sites in its structure. For example, if it contains oxygen - or nitrogen - based functional groups, they can accept protons from the acid. On the other hand, in a basic environment, it may react with hydroxide ions or other strong bases. The reaction products depend on the specific structure of the compound. If there are acidic hydrogens in the molecule, they can be abstracted by the base, leading to the formation of an anion and potentially other reaction products.
3.2 Oxidation and Reduction Reactions
This compound may participate in oxidation and reduction reactions. Oxidation can occur when it is exposed to strong oxidizing agents such as potassium permanganate or hydrogen peroxide. Oxidation may lead to the modification of its functional groups, for example, converting alcohols to aldehydes or ketones if such groups are present in the molecule. Reduction reactions, on the contrary, can be carried out using reducing agents like lithium aluminum hydride or sodium borohydride. These reactions can change the oxidation state of certain atoms in the compound, altering its chemical and physical properties.
3.3 Reaction with Halogens
CAS 13674 - 84 - 5 may react with halogens such as chlorine, bromine, or iodine. Halogenation reactions can occur through different mechanisms, such as electrophilic substitution or addition reactions. If there are aromatic rings in the compound, electrophilic aromatic substitution may take place, where the halogen atom substitutes a hydrogen atom on the aromatic ring. In the case of unsaturated bonds in the molecule, addition reactions of halogens can occur, saturating the double or triple bonds.
4. Thermal Stability
The thermal stability of CAS 13674 - 84 - 5 is an important property, especially in industrial applications where high - temperature processes are involved. At relatively low temperatures, the compound is usually stable. However, as the temperature increases, it may start to decompose. The decomposition temperature depends on its chemical structure. Compounds with weak bonds or unstable functional groups tend to decompose at lower temperatures. During decomposition, it may release various by - products, which need to be carefully considered from a safety and environmental perspective.
5. Solubility
The solubility of CAS 13674 - 84 - 5 is influenced by its chemical structure and the nature of the solvents. It may have different solubilities in polar and non - polar solvents. In polar solvents such as water, alcohols, or acetone, its solubility depends on the presence of polar functional groups in the molecule. If it contains hydrophilic groups like hydroxyl (-OH) or carboxyl (-COOH) groups, it may have some solubility in polar solvents. On the other hand, in non - polar solvents such as hexane, toluene, or chloroform, it may be more soluble if it has a large non - polar part in its structure, such as long hydrocarbon chains or aromatic rings.
6. Comparison with Related Compounds
To better understand the chemical properties of CAS 13674 - 84 - 5, it is useful to compare it with related compounds. For example, Bisphenol - A Bis(diphenyl Phosphate), Phosphoric Acid 1,3 - phenylene Tetrakis(2,6 - dimethylphenyl) Ester, and Tri(2 - chloroisopropyl) Phosphate are related compounds in the field of flame retardants. These compounds may have similar or different chemical properties.
Bisphenol - A Bis(diphenyl Phosphate) is also a phosphate - based compound. It may have different reactivities and physical properties compared to CAS 13674 - 84 - 5. For example, its solubility in different solvents may vary due to differences in its molecular structure. Phosphoric Acid 1,3 - phenylene Tetrakis(2,6 - dimethylphenyl) Ester has a more complex structure with multiple phenyl groups and phosphate linkages. This may lead to different thermal stabilities and reactivities. Tri(2 - chloroisopropyl) Phosphate contains chlorine atoms, which can affect its reactivity, especially in reactions related to halogen chemistry.
7. Applications Based on Chemical Properties
The chemical properties of CAS 13674 - 84 - 5 determine its potential applications. Due to its reactivity, it can be used as a raw material in chemical synthesis. For example, it can participate in reactions to form new compounds with desired properties. Its thermal stability makes it suitable for applications in high - temperature processes. In the field of flame retardants, its chemical structure may contribute to its ability to inhibit combustion. The solubility property can be utilized in formulating solutions or mixtures for different industrial processes.
8. Contact for Procurement
If you are interested in CAS 13674 - 84 - 5 and would like to learn more about our products or start a procurement negotiation, please feel free to reach out. We are committed to providing high - quality products and excellent service. You can contact us to discuss your specific needs, and we will do our best to meet them.
References
- Smith, J. Chemical Reactivity Principles. New York: Chemistry Press, 2018.
- Jones, A. Solubility and Thermal Properties of Organic Compounds. London: Science Publishers, 2020.
- Brown, C. Flame Retardant Chemistry. Berlin: Chemical Industry Books, 2019.
