How can we see visible light since electric and magnetic fields are invisible?

In summary: When you look at a wave, like you would a rowing boat on the water, what you are seeing is the oscillation of the water itself. When you look at a rowing boat and see the individual oarsmen, you are seeing the individual waves. Similarly, when you see a wave of light, you are seeing the individual photons.
  • #1
alkmini
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what do we mean exactly by visible light?
Since light is oscillating electric and magnetic fields, and both electric and magnetic fields are invisible, what do we actually see? is color the wave itself?when we see colors do we see the waves themselves and if their wavelength were bigger would we be able to see crests and troughs or is color a construction of our brain? when we see interference fringes do we see the waves themselves?
 
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  • #2
Photons are absorbed by different materials according to their wavelength. When light enters the eye it is focused on photoreceptive rod and cone cells (the former detects light intensity and the latter colour). As a photon travels through the cell it is absorbed by a rhodopsin molecule causing a conformational change. This actives a cell signalling pathway resulting in a signal being sent down the optic nerve to the brain. Different colours can be seen because the three types of cone cells (one to detect green, one red, one blue) have slightly different forms of rhodopsin that are activated by different wavelengths of light. The ratio of different cones cells activating creates different colours.
 
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  • #3
alkmini said:
what do we mean exactly by visible light?
Since light is oscillating electric and magnetic fields, and both electric and magnetic fields are invisible, what do we actually see? is color the wave itself?when we see colors do we see the waves themselves and if their wavelength were bigger would we be able to see crests and troughs or is color a construction of our brain? when we see interference fringes do we see the waves themselves?

To answer part of your question (I'm limited on time this morning), the very definition of "seeing" and "visible" is intimately related to the presence of electromagnetic fields and waves. "Visible" to humans means electromagnetic waves within a very very narrow frequency range. Our eyes have adapted to see/detect electromagnetic waves with frequencies between 400 THz and 750THz (THz = 1,000,000,000,000 Hz). A vast vast majority of light (read: electromagnetic waves) all around us does not fall within these wavelengths so our eyes are incapable of detecting or "seeing" most of the electromagnetic waves around us. However it DOES see that small frequency range and that is what we call "seeing" or "visible".
 
  • #4
thank both of your for your time but what i don't understand is, since electric and magnetic fields are invisible, how is it possible for oscillating and magnetic fields to be visible. Also what we see (the color) is the wave itself, as it happens when we look at water waves?
 
  • #5
alkmini said:
thank both of your for your time but what i don't understand is, since electric and magnetic fields are invisible, how is it possible for oscillating and magnetic fields to be visible. Also what we see (the color) is the wave itself, as it happens when we look at water waves?
Whether or not a photon is "visible" or "invisible" tends to refer to whether or not we can detect them with our natural sight. When a photon enters the eye the process I described above^ occurs. Different wavelengths of life (i.e. different colours) are absorbed by different materials. We have separate cells in our eye that detect different wavelengths and our brain processes that as different colours. Wavelengths that are invisible do not interact with the molecules in our eye and thus we cannot see them.

I have no idea what you mean by bringing water waves into it.
 
  • #6
do we actually see the wavelengths themselves that interact with the molecules with our eye, or is color something different? when I see green do i see just green or a wave of green, a wave with crests and troughs? ok a particular wavelength activates a cell, that makes me see green, but does this green oscillate, like the electromagnetic oscillation that made me see it ?
 
  • #7
You need to think about what you mean by 'visible'. Light is visible because it is absorbed by the cells of your retina which send signals via the optic nerve to neurons in your brain which are programmed to react to the signal to produce the sensation of sight. The cells of your retina are unaffected by static electric or magnetic fields, or by oscillating fields (waves) of all but a tiny range of frequencies, so you cannot 'see' them (which is just as well otherwise we would be blinded by the Earth's magnetic field).

Different cells absorb different frequencies of electromagnetic wave, so your brian is sent a different pattern of signals depending on the frequencies it is receiving: we experience this as colour.

I am not sure the analogy with water waves helps much here, except perhaps to think about a rowing boat and a cork floating on a pond. If you throw a small rock into the water, the cork bobs up and down: it 'sees' the waves, but the boat is unaffected.
 
  • #8
You do not see the oscillations: these are absorbed by electrons inside atoms within the retina. Think of it like a single water wave overflowing a bowl: you get water on the floor which stays there, it does not oscillate like the wave which made it get there. The brain sees the static pool of water on the floor, not the oscillating wave.

It is the same with light, the brain 'sees' the electrochemical signals from the retina which like the pool of water do not oscillate at the frequency of the waves that produced them.
 
  • #9
MrAnchovy said:
You do not see the oscillations: these are absorbed by electrons inside atoms within the retina. Think of it like a single water wave overflowing a bowl: you get water on the floor which stays there, it does not oscillate like the wave which made it get there. The brain sees the static pool of water on the floor, not the oscillating wave.

It is the same with light, the brain 'sees' the electrochemical signals from the retina which like the pool of water do not oscillate at the frequency of the waves that produced them.

thank you so much. you made it crystal clear
 
  • #10
alkmini said:
do we actually see the wavelengths themselves that interact with the molecules with our eye, or is color something different? when I see green do i see just green or a wave of green, a wave with crests and troughs? ok a particular wavelength activates a cell, that makes me see green, but does this green oscillate, like the electromagnetic oscillation that made me see it ?

You can answer that question yourself can you not - have you ever seen a crest or trough of light? Or the wavelength of light? when you look at something green does the color oscillate?

My guess is your answer will be no.

The oscillation of the light wave is what gives light its 'color' - it is an all or nothing. I put 'color' in quotes because light itself has no color. What you perceive as color ( in the visible spectrum ) is a certain frequency or wavelength of light impinging upon you eye. The eye is sensitive or if you prefer responds to those frequencies/wavelengths only within the visible spectrum. The eye responds to the frequency/wavelength of light and not to the crests or troughs as you call them.
So red has a certain frequency/wavelength, which is different from green, yellow, blue ...

You should note that a wave has certain characteristics such as frequency, wavelength, amplitude, and if you talk about only the crests or troughs then you are not talking about the wave but a certain feature that describes the wave.
 
  • #11
256bits said:
You can answer that question yourself can you not - have you ever seen a crest or trough of light? Or the wavelength of light? when you look at something green does the color oscillate?

My guess is your answer will be no.


If i don't see the color to oscillate, that could be a deficiency of my perception.
 
  • #12
256bits said:
Y
You should note that a wave has certain characteristics such as frequency, wavelength, amplitude, and if you talk about only the crests or troughs then you are not talking about the wave but a certain feature that describes the wave.

when i see interference fringes eg. do i not see minima and maxima which means crests that meet and add together?
 
  • #13
Visual perception is based on the rod and cone cells in your eyes absorbing energy to excite a molecule inside them which starts a chain of events that eventually results in you "seeing" something. This energy is delivered via an electromagnetic wave, aka light. The properties of the wave, such as wavelength, determine the amount of energy it has and whether it can get through to your retina and activate your rod and cone cells or not. Too long of a wavelength means that the light, the "photon", doesn't have enough energy to excite that molecule, while too short is blocked by the various parts of your eye.

In short, your eye's don't "see" the fields. The properties of the fields simply determine how the light interacts with your eye. If they are the right kinds of photons they will be absorbed by the right molecule in the right way and that will result in you seeing something.
 
  • #14
Drakkith said:
Visual perception is based on the rod and cone cells in your eyes absorbing energy to excite a molecule inside them which starts a chain of events that eventually results in you "seeing" something. This energy is delivered via an electromagnetic wave, aka light. The properties of the wave, such as wavelength, determine the amount of energy it has and whether it can get through to your retina and activate your rod and cone cells or not. Too long of a wavelength means that the light, the "photon", doesn't have enough energy to excite that molecule, while too short is blocked by the various parts of your eye.

In short, your eye's don't "see" the fields. The properties of the fields simply determine how the light interacts with your eye. If they are the right kinds of photons they will be absorbed by the right molecule in the right way and that will result in you seeing something.

I think I got it. It seems so obvious. Vision is the result of the interaction of the field with the eye .
The field is the source of my vision not its object
I am grateful to you for your clear explanation.
 
  • #15
alkmini said:
I think I got it. It seems so obvious. Vision is the result of the interaction of the field with the eye .
The field is the source of my vision not its object
I am grateful to you for your clear explanation.
Another thing to think about is that this applies to all of your senses. Everything you perceive about your environment is a model built by your brain on the basis of the sensory input but it isn't really what the world is like. This can be seen with any optical illusion such as this blind spot test. Simply close one eye, focus on the cross and move your head forward and back.

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Eventually the spot will disappear but not only will it disappear but your brain will fill in the missing space with the background.
 
  • #16
Ryan_m_b said:
Another thing to think about is that this applies to all of your senses. Everything you perceive about your environment is a model built by your brain on the basis of the sensory input but it isn't really what the world is like. This can be seen with any optical illusion such as this Simply close one eye, focus on the cross and move your head forward and back.


Eventually the spot will disappear but not only will it disappear but your brain will fill in the missing space with the background.

thanks for your reply. i love these physics forums. And i love this deceptive and mysterious world we live in
 
  • #17
alkmini said:
i love these physics forums. And i love this deceptive and mysterious world we live in
You're not the only one :wink:
 
  • #18
Ryan_m_b said:
Simply close one eye, focus on the cross and move your head forward and back. Eventually the spot will disappear but not only will it disappear but your brain will fill in the missing space with the background.

When I look at the left cross with my right eye, the dot on the right disappears.

When I look at the right dot with my left eye, the cross on the left disappears.

But it doesn't work in reverse - I can't change the combination.

In both cases, I don't have to move my head, I just have to view at 30 cms and the phenomenon is immediate.

Is this brainwork, or is it something to do with the positioning of the cones? Are the three types of cones evenly distributed at the back of the retina (except where the optic nerve goes out) or not? I don't understand these 2 different results I am getting depending on which eye I use, and I don't understand why I don't have to move my head backwards and forwards like you said. Can you explain more what is going on?
 
  • #19
Ok, I think I have got it. The place where there are no photocells i.e. where the optic nerve goes out, is on the 'nose' side in both eyes. I was assuming that the eyes are identically built, which is apparently not the case.
 
  • #20
Johninch said:
Ok, I think I have got it. The place where there are no photocells i.e. where the optic nerve goes out, is on the 'nose' side in both eyes. I was assuming that the eyes are identically built, which is apparently not the case.

Your body is symmetrical for the most part, or bilateral. Both sides are, to a certain extent, mirror images of each other.
 
  • #21
Drakkith said:
Your body is symmetrical for the most part, or bilateral. Both sides are, to a certain extent, mirror images of each other.

Cell division results in two copies of the cell, but after a predetermined number of repetitions the process stops. I wonder how the counter/register/trigger mechanism works? In the embryo the eye reaches a certain size and is then triggered to divide into two.

So actually we have only one seeing organ in two parts, which may explain why the optical nerve ending in the retina is near to the nose in both eyes. The division of the eye into two parts enables binocular vision and provides some backup, whereby the value of the backup function seems doubtful. Still, if one eye is slightly defective or weaker for some reason or gets slightly injured or diseased, the organism could probably still survive and reproduce.

What's interesting here too, is the complexity of the optical nerve channels to the brain, which has to reconcile and interpret two sets of data, as demonstrated by Ryan's exercise.

It seems that when it comes to the heart, evolution throws in the towel on this one. In the embryo the heart also starts as one and then divides into two, which then carry out different functions in the embryo. Later the two hearts fuse again and resume growing as one unit in a four chamber design. The single heart is for some reason is born on the left side i.e. the right heart somehow moves over and joins the left. It's claimed that a single heart system is robuster and avoids synchronisation issues, but I don't find that argument very convincing. Why then were there two hearts in the embryo? I hope I have understood this correctly.

It's not the same as the eye situation, as you don't need to see in the womb. But still, in comparison to the highly complex eye-brain situation, I would have thought that evolution could easily have dealt with two hearts, in order to spread the load and give us some back up.

I have diverged from the OP in reply to your comment on symmetry. I would be grateful for any PF or other links to information/discussions on symmetry.
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1. How is visible light different from electric and magnetic fields?

Visible light is a type of electromagnetic radiation that falls within a specific range of wavelengths in the electromagnetic spectrum. Electric and magnetic fields, on the other hand, are invisible forces that exist around charged particles and can interact with each other.

2. How does visible light travel through space?

Visible light is a form of energy that travels in waves. These waves are created by the oscillation of electric and magnetic fields, which are perpendicular to each other and to the direction of the wave's propagation. This allows visible light to travel through space without the need for a medium.

3. How do our eyes detect visible light?

Our eyes contain specialized cells called photoreceptors that are sensitive to visible light. When light enters our eyes, the photoreceptors convert the light into electrical signals that are sent to our brain, allowing us to see the world around us.

4. How are electric and magnetic fields related to visible light?

Electric and magnetic fields are the underlying mechanisms that allow visible light to exist and travel through space. As light waves propagate, the electric and magnetic fields oscillate perpendicular to each other, creating the characteristic wave-like pattern we associate with visible light.

5. How can we use visible light for scientific research?

Visible light is an important tool for scientific research as it allows us to observe and study the world around us. Scientists use specialized instruments such as telescopes and microscopes to manipulate and detect visible light, enabling them to gather valuable information about the universe and the smallest particles in our world.

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