Electronics are a part of our daily life. It might not be wrong to say that our lives have become dependent on these electronics. Whether it’s a coffee maker in your house or the phone you use, hybrid cars, your drive or technologies that facilitate. Each and every one of the electronics is composed of complex transistor structures and COBIT 5 training.

Living in such an age of rapidly advancing technology where newer inventions are a part of our daily life, electronics also need to get smarter. However, as an electronic device becomes smarter and more powerful, the complexity of its development also increases. The whole concept of technology, today, lies in the idea “smaller but powerful.” That’s why we see new phones and computers coming out every day with slim, thin bodies, faster processing powers, and COBIT 2019 training.

For quite a long-time silicon remained the only companion of transistors – the internal switches that perform the computing operations inside a computer. However not so long ago, the world saw its first Silicene Transistor. It means the future of the technology is all about powerful processing capabilities with minimum loss and consumption of energy.


Silicene is a 2-D version of silicon however with the thickness of a single layer of atoms. In its electrical properties, the first silicene transistor behaves like a super-strong highway for electrons but degrades within seconds, when exposed to air. To avoid this, researchers grew silicene on a silver base and used a layer of aluminum oxide to cease degradation. In the third step, they flipped it over, and with the help of custom-developed solution, etched out a silver slice in the middle while preserving the underlying silicene. Resulting in a successful silicene pathway for electrons to travel from the electrode to the other.


Nicknamed as graphene’s cousin, the most conductive substance present on earth, First Silicene Transistor has been a fantasy of computer scientists and physicists for decades. As, just like graphene, it has revolutionary, much efficient electrical properties that can change the face of computing altogether. Graphene possesses the potential for extraordinarily speedy circuits running through our computer chips. However, it lacks “bandgap”. Consequently, it is of no use for making computer chips. That’s how the concept of the first silicene transistor came to life.

Future approach:

Apart from resembling graphene in its electrical properties to a greater extent, Silicene is a form of silicon. That means it would be much easier for manufacturers to work with it as they are used to the substance. If scientists manage to get good electrical, stable properties out of it, Silicene transistors can transform the semiconductor industry.


  • Faster, more powerful technology devices.
  • Less consumption of energy.
  • The stronger and versatile build of transistors.
  • Newer, more diverse, and intelligent algorithms for a robotic




First Silicene Transistor is a great step ahead. If employed in the semiconductor industry with the right approach, not only these small devices will help build smarter, artificially intelligent robots, cars, smartphones, and computers, etc. but also a future with flexible, transparent electronics is the prediction.