Gamma rays have the highest frequency in the electromagnetic spectrum, with wavelengths less than 0.01 nanometers and frequencies greater than 10^19 Hz.
Gamma rays have the highest frequency among gamma rays, infrared waves, and radio waves.
There is no upper limit to how much energy (and frequency) an electromagnetic wave can have. The highest frequency waves are called gamma radiation.There is no upper limit to how much energy (and frequency) an electromagnetic wave can have. The highest frequency waves are called gamma radiation.There is no upper limit to how much energy (and frequency) an electromagnetic wave can have. The highest frequency waves are called gamma radiation.There is no upper limit to how much energy (and frequency) an electromagnetic wave can have. The highest frequency waves are called gamma radiation.
The highest frequency electromagnetic waves are gamma rays.
As the wavelength of a gamma ray decreases, its frequency increases. This is because frequency and wavelength are inversely proportional to each other, meaning that as one increases, the other decreases. So, as the wavelength of a gamma ray decreases, the number of waves passing a point per second (frequency) increases.
The highest frequency part of the electromagnetic spectrum is gamma rays, while the lowest frequency part is radio waves. Gamma rays have the shortest wavelengths and highest energy, while radio waves have the longest wavelengths and lowest energy.
Radio waves have the lowest frequency in all of the electromagnetic spectrum. The next higher frequency energy is microwave, visible light including ultraviolet, infrared, X-ray, then gamma ray
Gamma rays have the highest frequency among gamma rays, infrared waves, and radio waves.
No, radio waves are less energetic than gamma rays. This is so because gamma rays have a higher frequency causing the waves to be closer together. However both radio and gamma waves are a form of light (electromagnetic radiation).
There is no upper limit to how much energy (and frequency) an electromagnetic wave can have. The highest frequency waves are called gamma radiation.There is no upper limit to how much energy (and frequency) an electromagnetic wave can have. The highest frequency waves are called gamma radiation.There is no upper limit to how much energy (and frequency) an electromagnetic wave can have. The highest frequency waves are called gamma radiation.There is no upper limit to how much energy (and frequency) an electromagnetic wave can have. The highest frequency waves are called gamma radiation.
Gamma rays have the shortest wavelength. Electromagnetic wave is a kind of energy being propagated even through free space (vacuum). It is classified based on the mode of producing it as Radio waves, micro waves, infra red, visible, ultra violet, X-ray and Gamma ray. Out of these seven, radio waves have the lowest frequency and Gamma ray has the highest frequency. As frequency and wavelength are inversely related, radio wave would have the longest wavelength.
The highest frequency electromagnetic waves are gamma rays.
Gamma waves
As the wavelength of a gamma ray decreases, its frequency increases. This is because frequency and wavelength are inversely proportional to each other, meaning that as one increases, the other decreases. So, as the wavelength of a gamma ray decreases, the number of waves passing a point per second (frequency) increases.
The highest frequency part of the electromagnetic spectrum is gamma rays, while the lowest frequency part is radio waves. Gamma rays have the shortest wavelengths and highest energy, while radio waves have the longest wavelengths and lowest energy.
Gamma rays have a higher frequency than infrared waves. Gamma rays are on the electromagnetic spectrum with the shortest wavelength and highest frequency, while infrared waves have longer wavelengths and lower frequencies.
frequency, energy
Gamma Rays are the highest frequency waves. Lower than that are X-rays then Ultraviolet. Then visible light, infrared, microwave, and radio waves are the lowest frequency. Here is a link which gives more information http://imagine.gsfc.nasa.gov/science/toolbox/emspectrum1.html