We know that ultraviolet electromagnetic radiation is light that is higher in frequency than the light in the visible spectrum. It may be possible to argue that other shorter wave radiation could also be included, but the question has the feel of one that might be asked by an investigator who is beginning an inspection of the electromagnetic (EM) spectrum. Let's keep it simple and begin at the beginning, shall we?
The X-rays have shorter wavelengths ... shorter than the shortest wave to which the eye responds.
We know that gamma rays are electromagnetic energy, and they'll occupy a place on the electromagnetic (EM) spectrum. You can locate gamma rays right at the top end of the EM spectrum because their frequencies are so high (or their wavelengths are so short, if you prefer).
Electromagnetic radiation is a continuous spectrum of wavelengths from thousands of kilometres to wavelengths the size of fractions of an atom. They are all the same kind of radiation - the differences are only the wavelengths. They range from the longest - radio waves, then microwaves, infrared radiation, visible light, ultra violet light, X-rays and gamma rays. The sun emits all of these apart from gamma rays.
because they do not go to the same direction e.g the short-wave radiation heats the earth and the long-wave radiation heats the atmosphere.
The electromagnetic (EM) spectrum is the entire range of frequencies that electromagnetic radiation can have. The EM spectrum is divided into sections based on the common characteristics that certain frequency ranges have. These sections are, in order from low to high frequency, radio waves, microwaves, infrared waves, visible light (which from low to high frequency is further divided into red, orange, yellow, green, blue, indigo, and violet), ultraviolet waves, X-rays, and gamma rays. You can think of the EM spectrum as an invisible rainbow with visible light being a small part of it. And, like a rainbow, the edges of the divided sections are blurry; i.e. there is no exact frequency where one can say, for example, that this wave is no longer an X-ray, but is instead a gamma ray. it is waves of light in order of their wavelengths and frequencies APEX: A chart of frequencies of light waves.
X-rays and gamma rays can both fit that description.
The wavelengths of electromagnetic radiation extend from any long wavelength, withno upper limit no matter how long, continuously through all possible wavelengths, withno gaps, down to any short wavelength, with no lower limit no matter how short.
EM radiation is short for electromagnetic radiation. It is a wave in the electric and magnetic fields.EM radiation is short for electromagnetic radiation. It is a wave in the electric and magnetic fields.EM radiation is short for electromagnetic radiation. It is a wave in the electric and magnetic fields.EM radiation is short for electromagnetic radiation. It is a wave in the electric and magnetic fields.
EM radiation is short for electromagnetic radiation. It is a wave in the electric and magnetic fields.EM radiation is short for electromagnetic radiation. It is a wave in the electric and magnetic fields.EM radiation is short for electromagnetic radiation. It is a wave in the electric and magnetic fields.EM radiation is short for electromagnetic radiation. It is a wave in the electric and magnetic fields.
Type your answer here...The electromagnetic spectrum is the range of all possible frequencies of electromagnetic radiation.[1] The "electromagnetic spectrum" of an object is the characteristic distribution of electromagnetic radiation emitted or absorbed by that particular object.The electromagnetic spectrum extends from low frequencies used for modern radio to gamma radiation at the short-wavelength end, covering wavelengths from thousands of kilometers down to a fraction of the size of an atom. The long wavelength limit is the size of the universe itself, while it is thought that the short wavelength limit is in the vicinity of the Planck length, although in principle the spectrum is infinite and continuous.
EM is short for electromagnetic.
X-rays are part of the continuum of electromagnetic radiation. They have higher energy and shorter wavelengths than some other radiations.
The X-rays have shorter wavelengths ... shorter than the shortest wave to which the eye responds.
Yes, the shorter the wavelength, the higher the energy. Gamma waves have the shortest wavelengths of all the electromagnetic radiation waves and carry the greatest energy. Radio and TV waves have the longest wavelengths and carry the least energy.
If this question if referring to electromagnetic radiation (light) then the sun probably emits very small amounts of gamma rays, which have the shortest wavelengths of all electromagnetic radiation as well as larger amounts of x-Rays (the next wavelength larger). However, there are a variety of particles with larger masses and higher energies than that of photons. These particles are known as cosmic rays, which include electrons, muons, protons, neutrons, and even whole helium nuclei (called alpha particles). These higher mass particles can travel at near-light-speed velocities and as a result have very short wavelengths.
Energetic High-frequency Electromagnetic Radiation
We know that gamma rays are electromagnetic energy, and they'll occupy a place on the electromagnetic (EM) spectrum. You can locate gamma rays right at the top end of the EM spectrum because their frequencies are so high (or their wavelengths are so short, if you prefer).