Have you ever wondered how scientists manipulate matter at the atomic and molecular levels using nanotechnology? Nanotechnology involves working with materials at the nanoscale, which is on a scale of billionths of a meter. By manipulating matter at this size, researchers can create new properties and functionalities in materials using mechanisms involving nanometer-sized particles and …
Semiconductors and Optoelectronics
Semiconductors and optoelectronics are vital fields that have revolutionized the world of electronics and photonics.
Semiconductors are materials with electrical conductivity between conductors and insulators, and they form the foundation of modern electronics. They are used in the production of transistors, diodes, and integrated circuits, enabling the development of computers, smartphones, and other electronic devices.
Optoelectronics, on the other hand, combines the principles of optics and electronics to control and manipulate light for various applications.
It encompasses technologies such as light-emitting diodes (LEDs), laser diodes, and photodetectors.
Semiconductors and optoelectronics play a crucial role in advancing technology. It enable faster and more efficient electronic devices, high-speed communications, and energy-efficient lighting solutions.
Researchers and engineers in these fields continue to push boundaries, developing new materials, improving device performance, and exploring novel applications. The impact of semiconductors and optoelectronics to across industries and shape the way we live, communicate and interact with the world
Did you know that semiconductors, a key component of solid state physics, are the backbone of modern technology in fields such as computer science and engineering? These remarkable materials possess a unique property – they have electrical conductivity somewhere between conductors like copper and insulators like rubber. But what makes these nanostructures so special? Enter …