Heptafluorobutyranilide, a compound belonging to the class of perfluorinated chemicals, may not be familiar to the average individual in their daily routines. However, its presence in various products such as firefighting foams, non-stick coatings, and electronics serves a crucial role in enhancing performance and durability. Despite these beneficial properties, concerns have been raised regarding the potential environmental and health impacts associated with the widespread use of heptafluorobutyranilide and other perfluorinated compounds. As such, ongoing research and regulation efforts are aimed at better understanding and managing the risks associated with these chemicals in order to safeguard public health and the environment.
Table of Contents:
- 💡 Commercial Applications
- ⚗️ Chemical & Physical Properties
- 🏭 Production & Procurement
- ⚠️ Safety Considerations
- 🔬 Potential Research Directions
- 🧪 Related Compounds
💡 Commercial Applications
Heptafluorobutyranilide, also known as perfluorobutyranilide, has several commercial and industrial applications. It is commonly used as a surfactant in various industries, such as cosmetics, electronics, and textiles. Its unique properties, such as high thermal stability and chemical resistance, make it suitable for use in industrial processes where regular surfactants may not be effective.
In the pharmaceutical industry, heptafluorobutyranilide is used in the production of certain drugs and medications. Its biocompatibility and lack of toxicity make it safe for use in pharmaceutical formulations. It is often used as a solvent or carrier for active ingredients in drugs, especially those that require stable and nontoxic delivery systems.
Heptafluorobutyranilide is also used in medical devices and diagnostic tools due to its biocompatibility and chemical stability. It is commonly found in catheters, implantable devices, and imaging agents for medical purposes. Its ability to remain inert in biological environments makes it a preferred material for such applications in the medical field.
⚗️ Chemical & Physical Properties
Heptafluorobutyranilide is a white crystalline solid with no distinct odor. It is a chemical compound that is insoluble in water and has a low vapor pressure at room temperature.
The molar mass of Heptafluorobutyranilide is approximately 433.112 g/mol, with a density of around 1.38 g/cm³. This compound has a higher molar mass and density compared to common food items such as sugar (molar mass around 342.3 g/mol) and water (density of 1 g/cm³).
Heptafluorobutyranilide has a melting point of 146°C and a boiling point of 335°C. These values are significantly higher than those of common food items like butter (melting point around 32°C) and water (boiling point of 100°C).
Heptafluorobutyranilide is sparingly soluble in water and has a low viscosity. This compound exhibits lower solubility in water and lower viscosity compared to common food items such as salt (high solubility in water) and honey (high viscosity).
🏭 Production & Procurement
Heptafluorobutyranilide, a chemical compound used in various industrial applications, is primarily produced through a multi-step synthesis process in specialized chemical manufacturing facilities. The production typically begins with the reaction between heptafluorobutyric acid and aniline under specific conditions to yield Heptafluorobutyranilide.
Heptafluorobutyranilide can be procured from chemical suppliers who specialize in providing rare or specialty chemicals. It is important to ensure that the supplier adheres to strict quality control measures to guarantee the purity and potency of the compound. Once procured, Heptafluorobutyranilide can be transported in tightly sealed containers to prevent leakage or contamination during transit.
Given its unique chemical properties and potential hazards, the transportation of Heptafluorobutyranilide must comply with strict regulations established by international transportation authorities. Proper labeling, packaging, and handling procedures are essential to ensure the safe transportation of this compound from the manufacturer to the end user. Additionally, the receiving party must be aware of the necessary safety precautions and guidelines for handling Heptafluorobutyranilide upon delivery.
⚠️ Safety Considerations
Safety considerations for Heptafluorobutyranilide involve proper handling, storage, and disposal practices to minimize potential risks associated with this chemical compound. It is important to wear appropriate personal protective equipment such as gloves, goggles, and a laboratory coat when working with Heptafluorobutyranilide to prevent skin contact, eye irritation, or inhalation of vapors. The substance should be stored in a cool, dry, well-ventilated area away from incompatible materials and sources of ignition. In case of accidental exposure, follow established safety protocols for first aid and seek medical attention if necessary.
Hazard statements for Heptafluorobutyranilide include “Causes skin irritation,” “May cause respiratory irritation,” and “Harmful if swallowed.” These statements highlight the potential risks associated with direct contact or inhalation of the chemical compound. It is important to handle Heptafluorobutyranilide with caution and take necessary precautions to minimize exposure and prevent adverse health effects. Proper training and awareness of the hazards can help mitigate the risks associated with this substance.
Precautionary statements for Heptafluorobutyranilide include “Avoid breathing vapors, mist, or gas,” “Wash thoroughly after handling,” and “Use only outdoors or in a well-ventilated area.” These statements emphasize the importance of implementing safe practices when working with Heptafluorobutyranilide to reduce the likelihood of exposure and potential harm to personnel. Following these precautionary measures can help ensure the safe handling and use of the chemical compound, promoting a secure working environment for all individuals involved.
🔬 Potential Research Directions
Research on Heptafluorobutyranilide may focus on its potential applications in various industries such as pharmaceuticals, agriculture, and materials science. Studies could investigate the compound’s unique properties and its interactions with other chemicals to improve existing products or develop new materials with enhanced properties.
Furthermore, research on Heptafluorobutyranilide could explore its environmental impact and potential health risks. Studies could evaluate its persistence in the environment, bioaccumulation in organisms, and toxicity levels to assess the compound’s safety for use in various applications. This research could help in the development of regulations and guidelines for the handling and disposal of Heptafluorobutyranilide.
Additionally, investigations into the synthesis and purification methods of Heptafluorobutyranilide could lead to the development of more efficient and cost-effective processes. By understanding the mechanisms involved in its production, researchers could optimize the manufacturing process to reduce waste and improve yield. This research could contribute to the scalability and sustainability of Heptafluorobutyranilide production for commercial use.
🧪 Related Compounds
One similar compound to heptafluorobutyranilide is hexafluorobutyranilide. This compound has a slightly shorter carbon chain than heptafluorobutyranilide, containing only six carbon atoms. However, it shares the commonality of having multiple fluorine atoms attached to the carbon backbone, giving it similar chemical properties.
Another compound that is structurally similar to heptafluorobutyranilide is perfluorobutyranilide. In this compound, all the hydrogen atoms on the butyranilide backbone have been replaced with fluorine atoms, resulting in a completely fluorinated molecule. This compound is highly stable and exhibits similar chemical reactivity to heptafluorobutyranilide due to the presence of multiple fluorine atoms.
One more compound worth mentioning is pentafluorobutyranilide. Like heptafluorobutyranilide, this compound has a butyranilide backbone with multiple fluorine atoms attached. However, pentafluorobutyranilide only contains five fluorine atoms, making it structurally distinct from heptafluorobutyranilide. Despite this difference, pentafluorobutyranilide shares some chemical properties with its heptafluoro counterpart due to the presence of fluorine atoms.
