Gamma rays have the smallest wavelength among all types of radiation.
With longest wavelength to shortest Radio waves, micro waves, infra red, visible radiations, ultra violet, X-ray and Gamma ray
Gamma rays penetrate most deeply among the ionizing radiations because they have the highest energy and smallest wavelength, allowing them to easily pass through materials.
The color with the smallest (or as scientist term it, the shortest) wavelength is the color violet, also known as purple.
No, gamma rays have the shortest wavelength among all electromagnetic radiations. They have the highest frequency and highest energy in the electromagnetic spectrum.
The shortest wavelength of visible light is the wavelength of the last color you can see on the blue end of the rainbow or spectrum.
With longest wavelength to shortest Radio waves, micro waves, infra red, visible radiations, ultra violet, X-ray and Gamma ray
Gamma rays penetrate most deeply among the ionizing radiations because they have the highest energy and smallest wavelength, allowing them to easily pass through materials.
The color with the smallest (or as scientist term it, the shortest) wavelength is the color violet, also known as purple.
The UV radiation is stopped. These are high wavelength radiations.
the smallest infrared radiation wavelength is ranging from 0.75-1.3micrometre
No, gamma rays have the shortest wavelength among all electromagnetic radiations. They have the highest frequency and highest energy in the electromagnetic spectrum.
The shortest wavelength of visible light is the wavelength of the last color you can see on the blue end of the rainbow or spectrum.
Ozone absorbs the UV rays. These are high energy radiations.
Infrared radiation is of a much lower frequency (and a longer wavelength) than X-rays.
Ultraviolet
Violet has the smallest wavelength among the visible colors.
The smallest quantum of energy for a wavelength of light is a photon, which carries a fixed amount of energy determined by its frequency. This energy is described by the equation E = hf, where E is energy, h is Planck's constant, and f is the frequency of the light.