4-Quinoline Formic Acid CAS 486-74-8： A Breakdown of Its Properties and Applications

Abstract

This article provides a comprehensive breakdown of 4-Quinoline Formic Acid, CAS 486-74-8, focusing on its properties and applications. It delves into the chemical structure, physical properties, synthesis methods, and various industrial uses of this compound. Additionally, the article discusses the environmental impact, safety considerations, and regulatory aspects associated with the handling and use of 4-Quinoline Formic Acid. By examining these aspects, the article aims to provide a thorough understanding of this chemical and its significance in different sectors.

Introduction to 4-Quinoline Formic Acid

4-Quinoline Formic Acid, with the chemical formula C9H7NO3, is a derivative of quinoline and formic acid. It is a white crystalline solid that is soluble in water and organic solvents. This compound has gained attention due to its diverse range of applications in various industries, including pharmaceuticals, agriculture, and chemical manufacturing. In this article, we will explore the properties and applications of 4-Quinoline Formic Acid in detail.

Chemical Structure and Physical Properties

The chemical structure of 4-Quinoline Formic Acid consists of a quinoline ring substituted with a formic acid group. This unique structure contributes to its various physical properties. It has a melting point of approximately 224°C and a boiling point of around 312°C. The compound is slightly soluble in water and more soluble in organic solvents such as ethanol and acetone. These physical properties make it suitable for various applications where solubility and thermal stability are crucial.

Synthesis Methods

The synthesis of 4-Quinoline Formic Acid can be achieved through several methods, including the reaction of 4-aminobenzene with formic acid, the condensation of 4-aminobenzene with chloroacetic acid, and the reaction of 4-aminobenzene with formic anhydride. Each method has its own advantages and limitations, and the choice of synthesis route depends on factors such as cost, yield, and purity requirements. The synthesis process involves several steps, including the preparation of the starting materials, the reaction itself, and the purification of the final product.

Applications in Pharmaceuticals

4-Quinoline Formic Acid finds significant applications in the pharmaceutical industry. It is used as a precursor for the synthesis of various pharmaceutical intermediates and active pharmaceutical ingredients (APIs). For example, it is involved in the synthesis of antiviral drugs, analgesics, and anti-inflammatory agents. The unique properties of 4-Quinoline Formic Acid, such as its ability to undergo various chemical transformations, make it a valuable compound in drug development.

Applications in Agriculture

In the agricultural sector, 4-Quinoline Formic Acid is used as a herbicide and insecticide. It is effective in controlling a wide range of weeds and insects, making it a valuable tool for farmers. The compound's ability to be easily absorbed by plants and insects contributes to its effectiveness as an agricultural chemical. Additionally, its low toxicity to humans and animals makes it a preferred choice for sustainable farming practices.

Applications in Chemical Manufacturing

4-Quinoline Formic Acid is also utilized in the chemical manufacturing industry. It serves as a raw material for the production of dyes, pigments, and other specialty chemicals. The compound's versatility allows for the synthesis of various products with different properties, catering to the needs of various industries. Its use in chemical manufacturing highlights its importance as a key intermediate in the production of value-added chemicals.

Environmental Impact and Safety Considerations

While 4-Quinoline Formic Acid has numerous applications, it is essential to consider its environmental impact and safety aspects. The compound is toxic to aquatic organisms and can cause harm to the ecosystem if not handled properly. Therefore, appropriate disposal methods and safety measures must be implemented during its use and disposal. Regulatory agencies, such as the Environmental Protection Agency (EPA), have set guidelines and regulations to ensure the safe handling and use of this compound.

Regulatory Aspects

The handling and use of 4-Quinoline Formic Acid are subject to regulatory oversight. Various countries have specific regulations and guidelines in place to ensure the safe and responsible use of this compound. Compliance with these regulations is crucial for businesses involved in the production, distribution, and use of 4-Quinoline Formic Acid. Adhering to these regulations helps minimize the environmental impact and ensures the safety of workers and consumers.

Conclusion

In conclusion, 4-Quinoline Formic Acid, CAS 486-74-8, is a versatile compound with diverse applications in various industries. Its unique chemical structure and physical properties make it a valuable intermediate in pharmaceuticals, agriculture, and chemical manufacturing. However, it is crucial to consider its environmental impact and safety aspects while handling and using this compound. By adhering to regulatory guidelines and implementing appropriate safety measures, the benefits of 4-Quinoline Formic Acid can be maximized while minimizing potential risks.

Keywords: 4-Quinoline Formic Acid, CAS 486-74-8, properties, applications, pharmaceuticals, agriculture, chemical manufacturing, environmental impact, safety considerations, regulatory aspects.