Convert wavelength in centimetres [cm] to Electron Compton wavelength Online | Free frequency-wavelength Converter

A Key Scale in Radio and Microwave Technology

A centimetre (cm) is a unit of length equal to 10⁻² metres, and it is commonly used to express the wavelengths of radio and microwave radiation. Electromagnetic waves with wavelengths in the centimetre range typically fall within the radio frequency (RF) and microwave bands, covering frequencies from about 3 GHz to 30 GHz (for wavelengths between 10 cm and 1 cm). These waves are essential in a wide variety of applications, including Wi-Fi, Bluetooth, microwave ovens, radar, and satellite communications.

For example, Wi-Fi signals often operate at 2.4 GHz, which corresponds to a wavelength of about 12.5 cm, and microwave ovens use 2.45 GHz, or around 12.2 cm. These wavelengths are long enough to penetrate walls and other obstacles, making them ideal for communication and sensing. Centimetre-scale wavelengths also allow for the use of reasonably sized antennas in consumer devices and radar systems.

Using centimetres as a unit for wavelength provides a practical scale for understanding and designing devices that use radio and microwave frequencies. It simplifies communication between scientists, engineers, and technicians working in telecommunications, aerospace, medical imaging, and remote sensing.

A Quantum Limit of the Electron

The electron Compton wavelength is a fundamental constant in quantum physics that represents the limit at which the wave-like nature of an electron becomes significant in high-energy interactions. It is defined by the equation λ = h / (mₑ c), where h is Planck’s constant, mₑ is the mass of the electron, and c is the speed of light. The value of the electron Compton wavelength is approximately 2.426 × 10⁻¹² meters (or 2.426 picometers). This is significantly larger than the Compton wavelengths of heavier particles like the proton or neutron, reflecting the electron's much smaller mass.

The Compton wavelength is important because it sets a quantum limit on how precisely a particle's position can be defined without introducing enough energy to create particle-antiparticle pairs (like an electron and a positron). It plays a key role in quantum electrodynamics (QED), high-energy physics, and particle interactions involving photons and electrons. For instance, Compton scattering, a process where X-rays scatter off electrons, directly involves this wavelength. Understanding the electron’s Compton wavelength helps physicists analyze the structure of matter, radiation–matter interactions, and the behavior of particles at quantum scales.