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That'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.
What else can I help you with?
What is the electromagnetic spectrum Which part of the electromagnetic spectrum do plants use for photosynthesis?
Primarily Yellow but really it uses most of the visible spectrum, just some parts more than others. Green plants actually have five type of pigments that serve in photosynthesis. When the leave of the deciduous trees turn in autumn you can see the colours of many of these as they are selectively withdrawn.
What happens if you place a thermometer in any wavelength of visible spectrum?
A thermometer measures temperature by detecting infrared radiation. The visible spectrum does not emit significant amounts of infrared radiation, so placing a thermometer in any wavelength of the visible spectrum would not result in an accurate temperature reading.
Which of the alpha beta and gamma radiation is formed of 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).
What kind of energy is light energy?
Well, you might just put it in a separate category, and call it "light energy". But it is probably better to place it in the broader category of "electromagnetic waves".
When in nature do we see all the colors in the visible light spectrum?
One common place to see all colors in the visible light spectrum is in a rainbow, which is formed when sunlight disperses and refracts through water droplets in the atmosphere. In addition, certain minerals and gemstones can exhibit a wide range of colors due to their composition and structure.
is the the visible spectrum occupies most of the electromagnetic and sonar spectrum?
The visible spectrum is a tiny, almost negligible slice of the electromagnetic spectrum. 'Sonar' has no place in this discussion. It's not even electromagnetic.
Where would you place microwaves on the electromagnetic spectrum?
Microwaves would be found below infrared radiation, which is below visible light. They'd be at the top of what is called the radio spectrum.
Is white light a single color- Does it have a place in the electromagnetic spectrum like red and blue do?
white light is not a single color..it is made up of 7 different colors which include red and blue and yes it is there in the electromagnetic spectrum between ultraviolet and infrared radiation
Are sound waves part of the electromagnetic spectrum?
Sound waves and electromagnetic waves are different. Sound is composed of density waves in the air or some other form of matter. Sound is a mechanical compression-rarefaction wave. The different types of electromagnetic waves are gamma rays, X-rays, ultraviolet rays, visible light, infrared radiation, microwaves, and radio waves.
What is the electromagnetic spectrum Which part of the electromagnetic spectrum do plants use for photosynthesis?
Primarily Yellow but really it uses most of the visible spectrum, just some parts more than others. Green plants actually have five type of pigments that serve in photosynthesis. When the leave of the deciduous trees turn in autumn you can see the colours of many of these as they are selectively withdrawn.
Is infrared radiation visible?
It all depends upon where you place the boundaries of the infrared spectrum. The electromagnetic spectrum is a continuum and there is no exact boundary for any particular designation. If you define IR as that radiation below red which is invisible then Yes it is invisible.
What happens if you place a thermometer in any wavelength of visible spectrum?
A thermometer measures temperature by detecting infrared radiation. The visible spectrum does not emit significant amounts of infrared radiation, so placing a thermometer in any wavelength of the visible spectrum would not result in an accurate temperature reading.
What is the difference between infra-red and light?
Infra-red simply means less than red (referring to its place in the spectrum) and it is a wavelength that we cannot see. Similarly, ultra-violet means greater than violet and it is at the other end of the light spectrum, again of a wavelength that we cannot see. There are a lot of wavelengths of electro-magnetic radiation (as these are called) that we cannot see, radio waves being some of them.
Which of the alpha beta and gamma radiation is formed of 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).
What kind of energy is light energy?
Well, you might just put it in a separate category, and call it "light energy". But it is probably better to place it in the broader category of "electromagnetic waves".
When in nature do we see all the colors in the visible light spectrum?
One common place to see all colors in the visible light spectrum is in a rainbow, which is formed when sunlight disperses and refracts through water droplets in the atmosphere. In addition, certain minerals and gemstones can exhibit a wide range of colors due to their composition and structure.
What does radiation have to do with the speed of light?
All forms of electromagnetic radiation move from place to place at the speed of light.
