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How much of the electromagnetic spectrum is taken up by visible light?
Wiki User
∙ 12y ago
The EM spectrum ranges from very long radio waves at around 1000m or longer, to gamma rays at around 0.01 nanometers (nm). The visible part of the spectrum (for human eyes) ranges from 700 nm (red) to 400 nm (violet). One nanometer = 10-9 meter.
You may sometimes find reference to Angstroms, which used to be used for this range before SI was fully established. One Angstrom is 10-10 of a meter, ie 0.1 nm, so the range of visible light would be 7000 to 4000 Angstroms.
There is a nice diagram showing the visible range in the total spectrum, at Wikipedia
http://upload.wikimedia.org/wikipedia/commons/f/fl/EM_spectrum.svg
Wiki User
∙ 15y ago
Wiki User
∙ 14y agoLess than 5% of the electromagnetic spectrum is visible light, wavelength of approx 400 nanometers (violet) to 700 nanometers (red). The entire spectrum goes from gamma radiation (wavelength 1 trillionth of a nanometer) to radio waves (wavelength measured in kilometers)
Wiki User
∙ 12y agoThat's hard to discuss, because the electromagnetic spectrum has no ends.
If you name a frequency, then no matter how low it is, I can name a lower one,
and no matter how high it is, I can name a higher one. So, it's easy to describe
the size of the visible portion, but it's hard to describe the size of the full EM spectrum.
So let's just talk about the size of the part of the E&M spectrum that humans
use for radio communication, and ignore all the rest of it ... the infra-red, x-rays,
ultraviolet, gamma rays, all that other stuff. Only the part that we know how to
generate and modulate with very precise frequency control, and transmit and
receive over significant distances.
That's the portion of the E&M spectrum with frequencies from about 60 KHz
to about 100 GHz (wavelengths from about 3 millimeters to 5 kilometers).
'Linearly', that's a range of about 100 GHz bottom-to-top. But a much better
way to talk about parts of the E&M spectrum is logarithmically ... how many
'octaves' (doublings) or 'decades' (multiplied by 10) they cover.
Measured that way, our use of radio spans about 21 octaves, or about 6.2 decades.
Now we're ready to go look up the frequency/wavelength range of visible light.
A typical human eye will respond to wavelengths from about 390 to 750 nm
(3.9 to 7.5 x 10-4 millimeters). In terms of frequency, this corresponds to a band
in the vicinity of 400-770 THz (400,000 to 770,000 GHz).
That makes the visible range about 0.95 octave, or about 0.28 decade ... only
about 41/2% as wide as the range of wavelengths we use for radio communication!
Now, for fun, we'll try and include those other E&M phenomena that we've been ignoring.
We'll still have to decide where the ends of the spectrum are, because it really doesn't
have any.
For the bottom frequency, let's take 60 Hz. That's the small amount of RF that
radiates from power lines, which we always ignore. The wavelength is about
5,000 kilometers. (!)
Let's take gamma radiation for the top end ... the stuff generated in nuclear
decay, supernovas, black holes, that sort of thing. Dangerous stuff because
of its high energy. We're still here only because Earth's atmosphere absorbs
most of the gamma radiation from space, and not much of it ever reaches the
ground. Astronauts have to be shielded from it.
Gamma rays typically have frequencies above 10 exahertz (or >1019 Hz), and
wavelength less than 10 picometers (less than the diameter of an atom.)
So now, our 'expanded' range of electromagnetic spectrum covers 57.2 octaves,
or 17.2 decades, and the range of visible light is about 1.6% as wide as that.
Bottom line . . . we don't actually "see" a whole lot of the E&M spectrum, but
we know how to build instruments that detect the parts we can't see.
Wiki User
∙ 12y agoVisible light spectrum is approximately 400-800 Terahertz or 400 Terahertz wide.
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Why is it useful to examine the universe using parts of the electromagnetic spectrum other than visible light?
Different parts of the electromagnetic spectrum give different types of information.Different parts of the electromagnetic spectrum give different types of information.Different parts of the electromagnetic spectrum give different types of information.Different parts of the electromagnetic spectrum give different types of information.
Is it true or false that only portions of visible light can be taken up by chlorophyll?
True, obviously the green part of the spectrum is not used which is why chlorophyll looks green when illuminated with white light.
What is thermal infrared imagery?
Electromagnetic radiation in the range 5.6micrometre to 1.0 cm is called thermal infrared range.Green house gases absorb and emit radiation within this range.Green house gases in the earth's atmosphere are water vapour,carbon dioxide,methane,nitrous oxide and ozone
How did visible light waves help scientists decipher a pictures taken of Chaiten Chile?
Hi
What is taken in during light independent reactions?
Water is taken in. Light energy is used
Why is it useful to examine the universe using parts of the electromagnetic spectrum other than visible light?
Different parts of the electromagnetic spectrum give different types of information.Different parts of the electromagnetic spectrum give different types of information.Different parts of the electromagnetic spectrum give different types of information.Different parts of the electromagnetic spectrum give different types of information.
Is it true or false that only portions of visible light can be taken up by chlorophyll?
True, obviously the green part of the spectrum is not used which is why chlorophyll looks green when illuminated with white light.
What is the purpose of electromagnetic spectrum?
The electromagnetic spectrum is simply a way to display the range of electromagnetic energies in a manner that some associations can be discovered. Electromagnetic (EM) energy is composed of two waves, one electrostatic and one electromagnetic, that propagate at right angles to one another. Since we are looking at waves, it is natural to consider that they have different periods (the time it takes for one cycle to occur). We can then extend our thinking to consider the length of the wave, and also the frequency (the number of cycles per second) of the energy. Finally, we can consider the energy that is being propagated in the wave. If we spread out all the different frequencies on a chart or diagram with the lowest frequencies to the left and the highest frequencies to the right (as we usually do), we have a display of the electromagnetic spectrum. Radio waves will be on the left. They have the longest wavelength and the longest period, and also the lowest frequency. A lot of the spectrum is taken up by radio waves. Further to the right come microwaves, then the EM radiation a bit lower in frequency than visible light, which is the infrared region of the spectrum. The optical spectrum (visible light) is represented by the reds, oranges, yellows, etc., that we who are fortunate to be sighted can know. Beyond the violet visible light is the ultraviolet region, and then soft (lower energy) X-rays, and then the hard X-rays. Finally we find the gamma rays at the upper end of the spectrum. Looking at all of the diagram, which is a representation arranged to a useful purpose, we can discover a number of things about electromagnetic energy. The different spectra (radio, microwave, etc.) all have distinct characteristics that we can apply in daily life. Low frequency radio waves are used in submarine communication. (They penetrate water to a degree, and can actually travel in a curve around the world.) Microwaves make your cellular phone work, and they heat food in a microwave oven. We (most of us) are visual creatures, and visible light from the optical spectrum allows us to navigate our way about. At a medical clinic, hospital or dental office, an X-ray allows health professionals to quite easily see things that cannot be looked at well with other methods. There is a lot to learn, and a display of the electromagnetic spectrum opens a door to understanding this type of energy.
What is the purpose of electromagnetic?
The electromagnetic spectrum is simply a way to display the range of electromagnetic energies in a manner that some associations can be discovered. Electromagnetic (EM) energy is composed of two waves, one electrostatic and one electromagnetic, that propagate at right angles to one another. Since we are looking at waves, it is natural to consider that they have different periods (the time it takes for one cycle to occur). We can then extend our thinking to consider the length of the wave, and also the frequency (the number of cycles per second) of the energy. Finally, we can consider the energy that is being propagated in the wave. If we spread out all the different frequencies on a chart or diagram with the lowest frequencies to the left and the highest frequencies to the right (as we usually do), we have a display of the electromagnetic spectrum. Radio waves will be on the left. They have the longest wavelength and the longest period, and also the lowest frequency. A lot of the spectrum is taken up by radio waves. Further to the right come microwaves, then the EM radiation a bit lower in frequency than visible light, which is the infrared region of the spectrum. The optical spectrum (visible light) is represented by the reds, Oranges, yellows, etc., that we who are fortunate to be sighted can know. Beyond the violet visible light is the ultraviolet region, and then soft (lower energy) X-rays, and then the hard X-rays. Finally we find the gamma rays at the upper end of the spectrum. Looking at all of the diagram, which is a representation arranged to a useful purpose, we can discover a number of things about electromagnetic energy. The different spectra (radio, microwave, etc.) all have distinct characteristics that we can apply in daily life. Low frequency radio waves are used in submarine communication. (They penetrate water to a degree, and can actually travel in a curve around the world.) Microwaves make your cellular phone work, and they heat food in a microwave oven. We (most of us) are visual creatures, and visible light from the optical spectrum allows us to navigate our way about. At a medical clinic, hospital or dental office, an X-ray allows health professionals to quite easily see things that cannot be looked at well with other methods. There is a lot to learn, and a display of the electromagnetic spectrum opens a door to understanding this type of energy.
How does an infra-red camera work?
Infrared (IR) photos are taken with normal cameras using infrared film. The difference is the film used, not the camera. IR film is sensitive to the IR spectrum of light, not the visible spectrum.
What is a Definition of light energy?
Simple definition : An energy that comes from the light. Expanded definition : The radiant energy in the visible region or quantity of light. It is in the form of electromagnetic waves, and since the visible region is commonly taken as extending 380-760 nanometers in wavelength, the luminous energy is contained within that region. It is equal to the time integral of the production of the luminous flux. In photometry, luminous energy is the perceived energy of light. This is sometimes also called the quantity of light. Luminous energy is not the same as the radiant energy, the corresponding objective physical quantity. This is because the human eye can only see light in the visible spectrum and has different sensitivities to light of different wavelengths within the spectrum. When adapted for bright conditions (photopic vision), the eye is most sensitive to light at a wavelength of 555 nm. Light with the same power at longer or shorter wavelengths has a lower luminous energy.
What is a simple definition of light energy?
Simple definition : An energy that comes from the light. Expanded definition : The radiant energy in the visible region or quantity of light. It is in the form of electromagnetic waves, and since the visible region is commonly taken as extending 380-760 nanometers in wavelength, the luminous energy is contained within that region. It is equal to the time integral of the production of the luminous flux. In photometry, luminous energy is the perceived energy of light. This is sometimes also called the quantity of light. Luminous energy is not the same as the radiant energy, the corresponding objective physical quantity. This is because the human eye can only see light in the visible spectrum and has different sensitivities to light of different wavelengths within the spectrum. When adapted for bright conditions (photopic vision), the eye is most sensitive to light at a wavelength of 555 nm. Light with the same power at longer or shorter wavelengths has a lower luminous energy.
What is thermal infrared imagery?
Electromagnetic radiation in the range 5.6micrometre to 1.0 cm is called thermal infrared range.Green house gases absorb and emit radiation within this range.Green house gases in the earth's atmosphere are water vapour,carbon dioxide,methane,nitrous oxide and ozone
Two types of energy that exsits on the electromagnetic spectrum?
the waves travelling with velocity of light and consisting of oscillating electric and magnetic fields perpendicular to each other and also perpendicular to the direction of their propagation are called electromagnetic waves.such waves with different ranges of frequency constitute an electromagnetic spectrum.these electromagnetic waves are classified in to different types depending on their wavelenth they areradio wavesmicro wavesinfrared lightvisible lightultraviolet lightx raysgamma rays
How did visible light waves help scientists decipher a pictures taken of Chaiten Chile?
Hi
Is light a matter or energy?
The definition of matter is usually taken to be: anything that has mass and occupies space or has volume. The definition of light is those wavelengths of electromagnetic energy that can stimulate the retina of the eye. Light is a small part of the electromagnetic spectrum. This link will show you the elactromacnetic spectrum and its wavelengths. The Electromagnetic Spectrum The above definitions are fine but what do they mean. Mass is a quantity that all matter posseses. When that mass is in the presence of a gravitational field the mass will have weight. Now that the definitions are there let's see if we can put them together to answer your question. If light has mass and has a volume then it is matter, if neither are true then light is not matter. We have been experimenting with light for a long time. We have not been able to detect any mass associated with light. Light does react to gravity but we have found no evidence yet that it has mass. So it fails in the first test. Does light take up space? We have no evidence that I am aware of that light takes up space. Light can an will interact with matter in various ways. When the sun shines on your skin it feels warm. We use micro waves to cook food. You can think up other examples yourself. Light and mass are related. According to Einstein's famous equation E=mc^2. This tells us that mass can be converted into energy. The electromagnetic spectrum is a result of this mass to energy conversion going on in the stars. This is how our sun produces its energy. So, is light matter? To put it in more simple terms, light is energy and matter is made up of atoms.
Why is glass better than fused silica as prism construction?
Fused silica is used for ultraviolet radiation. For the visible spectrum some types of glasses are more dispersive - this means that the refractive index is more dependent on the wavelength of a radiation.
