Ovalene

Ovalene is a polycyclic aromatic hydrocarbon compound that has garnered considerable interest in the scientific community due to its unique chemical structure and potential applications in various fields such as organic electronics, materials science, and nanotechnology. In everyday life, Ovalene may not have a direct impact on most individuals. However, its study and potential utilization in cutting-edge technologies could contribute to advancements that shape the future of industries and society as a whole.

Table of Contents:

💡  Commercial Applications

Ovalene, a polycyclic aromatic hydrocarbon with a unique oval-shaped structure, has found a variety of commercial and industrial applications. Due to its high thermal stability and conductivity, Ovalene is commonly used as a component in electronic devices such as organic light-emitting diodes (OLEDs) and organic thin-film transistors. Additionally, Ovalene has been investigated for its potential use in solar cells and as a colorant in inks and dyes due to its vibrant red color.

In the field of drug and medication applications, Ovalene has shown promise as a potential antiviral agent. Research studies have shown that Ovalene exhibits antiviral activity against certain viruses, making it a candidate for the development of novel antiviral therapies. Additionally, Ovalene has been studied for its potential anti-inflammatory properties, which could be beneficial in the treatment of inflammatory conditions such as arthritis. Further research is needed to fully understand the therapeutic potential of Ovalene in the field of medicine.

⚗️  Chemical & Physical Properties

Ovalene is a polycyclic aromatic hydrocarbon that appears as a colorless crystalline solid. It is odorless, with no distinct scent detected by human olfactory receptors.

The molar mass of Ovalene is approximately 252.30 g/mol, with a density of 1.28 g/cm^3. In comparison to common food items, Ovalene has a higher molar mass and density than substances such as sugar and salt.

Ovalene has a melting point of approximately 275-277°C and a boiling point of around 527-529°C. When compared to common food items, Ovalene has significantly higher melting and boiling points than substances like butter and chocolate.

Ovalene is insoluble in water and has a high viscosity. In contrast, common food items such as sugar and salt are soluble in water and have lower viscosities.

🏭  Production & Procurement

Ovalene is a polycyclic aromatic hydrocarbon compound, which is produced through a process of synthesis in a laboratory setting. This compound is derived from a series of chemical reactions involving aromatic hydrocarbons, leading to the formation of a ring structure with a distinctive oval shape. The production of Ovalene typically requires precise control of reaction conditions and careful purification techniques to obtain a high-purity end product.

Ovalene can be procured through specialty chemical suppliers or chemical manufacturing companies that produce and distribute this compound. It is often available in the form of a powder or crystalline solid, packaged in sealed containers to ensure purity and stability during transport. The procurement of Ovalene may involve placing an order with a supplier, providing necessary documentation and certifications for handling hazardous materials, and arranging for transportation to the desired destination.

Transporting Ovalene typically involves using specialized containers that are designed to prevent contamination or leakage during transit. This compound is often classified as a hazardous material due to its chemical properties, requiring compliance with regulations for handling and transportation of dangerous goods. Proper labeling, documentation, and handling procedures are essential to ensure the safe delivery of Ovalene to its intended destination.

⚠️  Safety Considerations

Safety Considerations for Ovalene:

Ovalene, a polycyclic aromatic hydrocarbon, poses several safety considerations due to its potential hazards. It is important to handle Ovalene with care to prevent skin and eye irritation. Inhalation of Ovalene vapors should be avoided, as it may cause respiratory irritation and potentially lead to lung damage. Proper ventilation and personal protective equipment, such as gloves and goggles, should be used when working with Ovalene to minimize the risk of exposure.

Hazard Statements for Ovalene:

The hazard statements for Ovalene include “Causes skin and eye irritation” and “May cause respiratory irritation.” These statements emphasize the potential risks associated with handling Ovalene and the importance of taking proper safety precautions. It is crucial to be aware of these hazards and to follow appropriate safety measures when working with Ovalene to mitigate the risks of exposure and injury.

Precautionary Statements for Ovalene:

Precautionary statements for Ovalene include “Avoid breathing vapors, mist, or spray” and “Wear protective gloves/eye protection.” These statements highlight the necessary precautions that should be taken when handling Ovalene to ensure the safety of individuals working with this substance. Following these precautionary measures is essential to minimize the risk of exposure and to protect against potential health hazards associated with Ovalene.

🔬  Potential Research Directions

Potential research directions of Ovalene include its application in organic electronics due to its unique properties as a polycyclic aromatic hydrocarbon. Studies may focus on enhancing the charge transport properties of Ovalene-based materials for use in flexible electronic devices. Additionally, investigations into the synthesis of derivatized forms of Ovalene could open up new avenues for its utilization in optoelectronic applications.

Furthermore, research on the photophysical properties of Ovalene could lead to the development of novel light-emitting materials. Understanding the excited state dynamics of Ovalene and its derivatives may offer insights into their potential use in organic light-emitting diodes (OLEDs) and other light-emitting devices. Exploring the fluorescence and phosphorescence behavior of Ovalene could provide valuable information for optimizing its performance in such applications.

Moreover, investigations into the chemical reactivity of Ovalene could offer opportunities for its functionalization and incorporation into various materials. By studying the reactions of Ovalene with different reagents, researchers may be able to create new derivatives with tailored properties for specific applications. Additionally, exploring the potential use of Ovalene as a building block in the synthesis of complex organic molecules could lead to advancements in the field of organic chemistry.

One similar compound to Ovalene based upon molecular structure is circumnumfloulene. This compound contains a similar arrangement of benzene rings as Ovalene, resulting in a symmetrical and planar structure. The conjugated system of double bonds in circumnumfloulene also contributes to its aromatic properties.

Another compound with a molecular structure similar to Ovalene is hexabenzocoronene. This polycyclic aromatic hydrocarbon is composed of six fused benzene rings, similar to Ovalene’s arrangement. The large and planar structure of hexabenzocoronene gives rise to its unique electronic properties, making it a potential candidate for various applications in materials science and organic electronics.

Furthermore, a compound known as circumcircumcoronene exhibits a molecular structure akin to Ovalene. This polycyclic aromatic hydrocarbon is composed of multiple fused benzene rings, similar to Ovalene’s structure. The highly symmetric and planar arrangement of circumcircumcoronene contributes to its aromatic nature, making it a versatile compound in various research fields involving aromatic systems.

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