A synthetic polymer which are similar to natural fullerene, but has a number of significant differences. Many people don’t know that fullerene is not actually a type of polymer at all but more of a synthetically-produced version.
The synthetic material was first developed in the 1950s, and since then it has played an important role in enhancing many different sectors. One of its most common uses today is in the manufacturing of plastic composites and roofing materials. In this article I’ll describe what it’s used for, and why it’s important for manufacturing applications. Hopefully by the end of this article you should understand why it’s so useful.
The primary use of the material is in the production of plastic composites – sheets of thin glass or polycarbonate carbon that are used in roll-to-roll manufacturing. The original material contains around two hundred and twenty trace elements, including twelve aluminium ions. In recent years however, engineers have been trying to refine this substance to make it even more effective. Currently, the best formulations contain around thirty-two elements, including three aluminium and one titanium atoms.
c60Fullerene acts as a poor conductant; in other words, it has low thermal conductivity. This means it doesn’t conduct heat, which is a significant problem when you’re using it for something like roofing materials. Unfortunately, it also absorbs ultraviolet radiation. As well as this, it has poor electrical conduction properties, so it isn’t useful for things such as light sensors or lasers. A major difficulty with this material is that it doesn’t stop gases from travelling through it, so it acts as a poor conductor for solids, liquids and gaseous vapours.
The unique physical and chemical properties of the material mean it can only be manufactured in high temperatures, and so it is ideally suited to use as an ingredient in fuel cell cars and air compressors. In addition to being highly effective at conducting heat, the lattice structure of the carbon atoms and their orientation enables them to trap molecules and polymer chains quickly and easily. It has also been found that fullerene can produce high pressure as it is compressed. These properties make it ideal for use in aircraft engines.
However, while these properties make it a great material for high-temperatures, its lack of stiffness limits its applications to low-pressure applications, where it may be less effective. Its most common applications are in industries where one wants a material that is rigid enough to support heavy loads without becoming damaged. It was introduced into the market by NASA to be used in its satellite craft. It was rejected by the space agency because of its low tensile strength, but NASA discovered that adding a polymer additive to the mix improves its structural integrity.
A major advantage of this amazing substance is that it is completely recyclable. Unlike the majority of other substances, carbon and fibre can be manufactured synthetically, meaning that they are made from nothing but pure carbon and pure fibre. It is possible to recover fibre and carbon to a usable state with little effort from a recycling company, making it highly economical to produce.