When dopants are introduced to Silicon Carbide, it transforms into a semiconductor. Silicon carbide becomes a p-type semiconductor when dopants such as boron and aluminium are introduced. Dopants such as nitrogen and phosphorus, on the other hand, make silicon carbide an n-type semiconductor. Because of its hardness, silicon carbide is often used as an abrasive. It is used to make grinding wheels, cutting tools, and sandpaper. Silicon carbide abrasives are typically less expensive than comparable quality abrasives. Steel, aluminium, cast iron, and rubber are among the materials ground with abrasives.

When compared to silicon, Silicon Carbide is a better alternative for powering electric vehicles. Electric cars fueled by silicon carbide are extremely efficient and cost-effective. Famous manufacturers such as Tesla use silicon carbide in the production of their electric vehicles to boost efficiency and range. Diamonds are structurally similar to silicon carbide. As a result, it is used in the jewellery sector. It is more glossy, less expensive, more durable, and lighter than diamond. Silicon carbide's characteristics make it a suitable substitute for diamonds in the jewellery business.

Read More- https://coherentmarketinsightsus.blogspot.com/2023/04/pure-silicon-and-carbon-are-combined-to.html