You are misunderstanding what you've read. The best measurements we have say that whatever the electron's radius is, it's something less than ##10^{-22}## meters. This is consistent with it being a point particle of size zero (to the extent that "size" is even a meaningful concept for a quantum object such as an electron).Yashtir Gopee said:The electron has a radius of 10^-16m.
There are indeed quantum mechanical limits to how small a transistor can be made, but to understand them you need to understand the quantum mechanical description of electrons.Does it oscillate and how much is its displacement?
Actually I would like to know till how much can we reduce the size of a transistor (assuming we get the appropriate materials and environment for the current limitations).
Confinement of individual electrons[edit]
Individual electrons can now be easily confined in ultra small (L = 20 nm, W = 20 nm) CMOS transistors operated at cryogenic temperature over a range of −269 °C (4 K) to about −258 °C (15 K).[65] The electron wavefunction spreads in a semiconductor lattice and negligibly interacts with the valence band electrons, so it can be treated in the single particle formalism, by replacing its mass with the effective mass tensor.
Yashtir Gopee said:Does it oscillate and how much is its displacement?
Indeed you are. This thread is closed.Yashtir Gopee said:Maybe I'm going a little off-topic now,
The behavior of electron waves in transistors is crucial to the functioning of these essential electronic components. Transistors rely on the movement and manipulation of electrons to amplify and switch electrical signals. Understanding the behavior of electron waves allows scientists and engineers to design and optimize transistors for various applications.
Electron waves in a transistor exhibit both particle-like and wave-like properties. As they pass through the various layers and materials of the transistor, they can be reflected, diffracted, and interfere with each other. These behaviors can be controlled and manipulated through the design and structure of the transistor.
Quantum mechanics is the branch of physics that explains the behavior of particles at the atomic and subatomic level. In the case of transistors, it helps us understand the behavior of electrons as both particles and waves, and how they interact with the materials and structures of the transistor. Without quantum mechanics, we would not have a complete understanding of electron wave behavior in transistors.
The behavior of electron waves in transistors can greatly impact their performance. For example, interference between electron waves can cause signal loss and decrease the efficiency of the transistor. On the other hand, proper manipulation of electron waves can lead to better amplification and switching capabilities of the transistor.
Current research in this field focuses on improving the speed, efficiency, and reliability of transistors through a better understanding and control of electron wave behavior. This includes exploring new materials and structures for transistors, as well as developing advanced techniques for manipulating electron waves. Other research areas include quantum computing and the development of new transistor designs for nanoscale technologies.