CAS 123 - 25 - 1 refers to 1,10 - Decanediol, which is an important organic compound with a wide range of applications in various industries such as cosmetics, pharmaceuticals, and chemical synthesis. As a supplier of CAS 123 - 25 - 1, I am often asked about its reduction products. In this blog, I will delve into the possible reduction products of CAS 123 - 25 - 1 and explore their significance.
Understanding CAS 123 - 25 - 1: 1,10 - Decanediol
1,10 - Decanediol is a diol with the chemical formula C₁₀H₂₂O₂. It is a white crystalline solid that is soluble in organic solvents and has a melting point of around 71 - 73 °C. This compound is widely used as a moisturizer in cosmetics due to its ability to enhance the skin's water - holding capacity. It also has antibacterial and antifungal properties, making it a valuable ingredient in personal care products.
Reduction Reactions of 1,10 - Decanediol
Reduction reactions involve the gain of electrons or a decrease in the oxidation state of a molecule. For 1,10 - Decanediol, several types of reduction reactions can occur, depending on the reaction conditions and the reducing agents used.
Catalytic Hydrogenation
One of the common reduction methods is catalytic hydrogenation. In the presence of a suitable catalyst such as palladium on carbon (Pd/C), hydrogen gas can react with 1,10 - Decanediol under high pressure and temperature. The reaction can potentially lead to the formation of decane (C₁₀H₂₂).
The overall reaction equation for the catalytic hydrogenation of 1,10 - Decanediol can be represented as follows:
C₁₀H₂₂O₂ + 2H₂ → C₁₀H₂₂+ 2H₂O
Decane is a straight - chain alkane that is widely used as a component in fuels and solvents. It has a boiling point of around 174 °C and is a colorless liquid at room temperature. The production of decane from 1,10 - Decanediol through catalytic hydrogenation can be an interesting route for the conversion of renewable resources, as 1,10 - Decanediol can be derived from natural sources.
Reduction with Metal Hydrides
Metal hydrides such as lithium aluminum hydride (LiAlH₄) and sodium borohydride (NaBH₄) are also commonly used reducing agents. However, for 1,10 - Decanediol, the reaction with these metal hydrides may not result in a significant reduction since the diol is already in a relatively reduced state.
LiAlH₄ is a strong reducing agent that can reduce a variety of functional groups such as carbonyl groups to alcohols. But in the case of 1,10 - Decanediol, which does not have a carbonyl group, the reaction may be limited. Sodium borohydride is a milder reducing agent and is also less likely to cause a significant reduction of 1,10 - Decanediol.
Significance of Reduction Products
The reduction products of 1,10 - Decanediol, such as decane, have several important applications. In the fuel industry, decane can be used as a component in gasoline and diesel fuels to improve their combustion properties. It can also be used as a solvent in the chemical industry for various extraction and purification processes.
In addition, the ability to convert 1,10 - Decanediol into other valuable compounds through reduction reactions provides an opportunity for the development of new chemical processes. This can contribute to the sustainable production of chemicals by utilizing renewable resources.
Related Compounds and Their Reduction Products
It is also interesting to compare the reduction products of 1,10 - Decanediol with those of other related compounds. For example, 2-Ethyl Anthraquinone 2-EAQ CAS 84-51-5 is an important intermediate in the production of hydrogen peroxide. The reduction of 2 - Ethyl Anthraquinone can lead to the formation of 2 - Ethyl - 9,10 - dihydroxyanthracene, which then reacts with oxygen to regenerate 2 - Ethyl Anthraquinone and produce hydrogen peroxide.
Another compound, Triphenylphosphine TPP CAS 603-35-0, is often used as a ligand in organometallic chemistry. Although it is not directly related to 1,10 - Decanediol, understanding its chemical behavior and reduction products can provide insights into the general principles of reduction reactions. Triphenylphosphine can be oxidized to triphenylphosphine oxide, and in some cases, it can be reduced back to triphenylphosphine using appropriate reducing agents.
4-Hydroxybenzenesulfonic Acid P-Phenolsulfonic Acid Phenol-4-sulfonic Acid CAS 98-67-9 is a sulfonic acid derivative. Reduction of this compound may involve the reduction of the sulfonic acid group, which can be a complex process and may require specific reaction conditions and reducing agents.
Conclusion
As a supplier of CAS 123 - 25 - 1 (1,10 - Decanediol), understanding the reduction products of this compound is crucial for both scientific research and industrial applications. The catalytic hydrogenation of 1,10 - Decanediol to produce decane is a promising reaction that can lead to the development of new chemical processes and the production of valuable products.
If you are interested in purchasing CAS 123 - 25 - 1 for your research or industrial needs, please feel free to contact us for further details and to start a procurement negotiation. We are committed to providing high - quality products and excellent customer service.
References
- March, J. (1992). Advanced Organic Chemistry: Reactions, Mechanisms, and Structure. John Wiley & Sons.
- Carey, F. A., & Sundberg, R. J. (2007). Advanced Organic Chemistry Part A: Structure and Mechanisms. Springer.
- Vogel, A. I. (1989). Vogel's Textbook of Practical Organic Chemistry. Longman.
