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Posted

Does light undestroyable? and it will just keep reflecting to different place?

Or will it be absorbed by something? Or will light just dim out on its own?

Posted

If a photon disappears it's because it's absorbed by a material. A photon is a discrete packet of energy and makes whatever material it's being absorbed by vibrate, the magnitude of the vibration dependent on it's wavelength, aka color (in the visible spectrum). It's energy, and when it's spent, it's spent (meaning the energy is transfered to the material it's being absorbed by and no more photon). Now absorbing photons can make a material emit photons, but I think that may be outside of the realm of your question as it has nothing to do with the general "death" of a photon.

 

I hope that answers your question.

Posted

Light does get absorbed as silkworm says.

 

Also light spreads out. For example in a light bulb all the light starts in the bulb but spreads out across the whole room. So if you put the light bulb at the end of your garden then the light would have to spread out all over your garden and your house and maybe a bit into your room (if your room was at the back of the house with a window), this will make it seem a lot dimmer. The bulb still produces the same amoutn of light, but it spreads out a lot more so seems dimmer.

 

Across massive distances light spreads out so much that it can become so dim that you cannot see it. In reality there is still a tiny bit of light coming from that bulb to you, just not enough for your eyes to see it. Theoretically even if the light bulb was an infinite distance from you then there would still be a bit of light going straight to you, but again it would be far too little to see with your eyes.

Posted

But where do those absorbed photon go? Would the Universe eventually be full of light?

 

And Why can't you fill up and pop a box with light?

Posted
But where do those absorbed photon go? Would the Universe eventually be full of light?

It turns into energy' date=' which is represented by the molecular vibrations

 

And Why can't you fill up and pop a box with light?

 

because photons are massless... they don't take up three demensional space.

Posted

In a similar related concept, when something emits light does the number of photons emitted depend on the energy used to emit them? If that makes sense.

Posted
In a similar related concept, when something emits light does the number of photons emitted depend on the energy used to emit them? If that makes sense.

 

Yes an no, photons come in distinct energy groups, you can't just have any energy value for a photon, the groups are the only valid energy levels.

 

Thats the way I understand it, not shure how accurate that statement is :)

 

As for light being absorbed, I think of it this way:

 

A photon is a concept to represent light as energy in a particle form, when its absorbed the energy of it and the thing it joins with unify becomming one. There never was a problem because the photon is simply a concept in this case to represent the energy trasfered, make sence to anyone?

 

Cheers,

 

Ryan Jones

Posted
In a similar related concept, when something emits light does the number of photons emitted depend on the energy used to emit them? If that makes sense.

 

As RyanJ said, yes and no: it depends on the circumstances. In a single atomic transition, the energy is related to the frequency, but you will get only a single photon. More energy in the transition will give you a higher-energy photon, but not more photons, for a single interaction. But having more energy by having more atoms in an excited state will give you more photons.

Posted
because photons are massless... they don't take up three demensional space.
Although photons do have a momentum so when they hit a wall they will exert a force on it.
Posted
because photons are massless... they don't take up three demensional space.

 

However, you can be in a situation where you can't have a photon (of a particular wavelength) because the volume is too small; the cavity won't support the standing-wave mode. But once you satisfy the boundary conditions you can put as many photons into it as you want, within engineering limitations.

Posted
But where do those absorbed photon go? Would the Universe eventually be full of light?

 

When the photon is absorbed the vibration it causes either causes friction and is lost as heat, or it can do useful work overcomming an activation barrier or decomposing a molecule. It sort of depends on the situation.

 

And no, that says nothing about the universe filling with light.

 

And Why can't you fill up and pop a box with light?

 

I don't know what you're saying here. If you're saying why can't you hold a photon in a box? Well, you can. Just not for very long. And it's more of a mirrored pocket than a box. If you're asking why can't you stuff photons in a box, and fill it up until it bursts, well, you can do that too, if you have material inside that decomposes to a gas when exposed to a particular area of the electromagentic spectrum.

 

In a similar related concept, when something emits light does the number of photons emitted depend on the energy used to emit them?

 

You can take Planck's equation E=hv and say that E/h = v, which says verbally Energy over Planck's constant = frequency. Wavelength, frequency, and energy are all intertwined.

Posted
Does light undestroyable? and it will just keep reflecting to different place?

Or will it be absorbed by something? Or will light just dim out on its own?

 

All you need to know is that energy is conserved but it can be changed from one form to another. A photon is just one form that that energy can take. When light from the sun strikes something the light of the wavelength which matches the color of the object is reflected and the rest is absorbed where it is changed to other forms of energy. It could be heat, other EM waves, or electricity, etc. This is a simple conservation of energy question. As far as the box of light goes it sounds to me that you want a blackbody.

Posted

i have a question.

 

If light can bounce of objects, doesnt it mean it has to reduce speed to zero and go in a negative direction? Which would mean light doesnt have a constant speed

Posted

It is all an instant thing.

 

A photon travels at c until it is absorbed at which point it ceases to exist... when an electron jumps to a lower energy level it releases a photon, the photon has speed c as soon as it comes into existance, it keeps this speed until it ceases to exist (upon absorption).

Posted
When the photon is absorbed the vibration it causes either causes friction and is lost as heat

 

Friction is really a macroscopic property. The vibration is the manifestation of thermal energy.

Posted
Friction is really a macroscopic property. The vibration is the manifestation of thermal energy.

 

I do a pretty decent amount of analytical chemistry. We use spectroscopy to stretch, bend, and make molecules and atoms vibrate by exposing them to sets of wavelengths in the electromagnetic spectrum. You can heat up molecules and make them vibrate, and you can also make the molecules vibrate, stretch, bend by exposing them to certain wavelengths and that energy eventually leaves.

Posted
I do a pretty decent amount of analytical chemistry. We use spectroscopy to stretch, bend, and make molecules and atoms vibrate by exposing them to sets of wavelengths in the electromagnetic spectrum. You can heat up molecules and make them vibrate, and you can also make the molecules vibrate, stretch, bend by exposing them to certain wavelengths and that energy eventually leaves.

 

And I use lasers to cool atoms down. Temperature is proportional to the kinetic or vibrational energy. But heat, or thermal energy, is not some separate phenomenon from this. Saying that a photon is absorbed and the energy is lost as heat implies (to me, anyway) that the photon absorption wasn't heat transfer in the first place, and that's wrong. It's all heat transfer, so that's too general a term to apply to the individual processes.

Posted
And I use lasers to cool atoms down. Temperature is proportional to the kinetic or vibrational energy. But heat, or thermal energy, is not some separate phenomenon from this.

 

What happens to photons when producing latent heat...they get absorbed, the kinetic energy stops rising, the bonds break to change state...then what. What happens to the photons after this point, or do they literally get fizzled out when breaking the bonds, or do they eventually get released through some other means ??

Posted
What happens to photons when producing latent heat...they get absorbed, the kinetic energy stops rising, the bonds break to change state...then what. What happens to the photons after this point, or do they literally get fizzled out when breaking the bonds, or do they eventually get released through some other means ??

 

Once the photon is absorbed there is no more photon. The energy is in some other form. Other processes can make new photons.

Posted
Once the photon is absorbed there is no more photon. The energy is in some other form. Other processes can make new photons.

 

Thanks Swansont. Although 5614 kinda already answered the question, I just wanted it clarified with regards to latent heat.

Posted
When the photon is absorbed the vibration it causes either causes friction and is lost as heat' date=' or it can do useful work overcomming an activation barrier or decomposing a molecule. It sort of depends on the situation.

[/quote']

 

Ignoring swansont's comments concerning heat (in which his is correct -- if you consider temp to be average kenetic energy). There are very few processes for which an increase in vibrational enegy level of a molecule will provide the nessesary activation energy. Most chemical processes (processes in which electrons move about) require much larger activation energies than several thousand wavenumbers. I am not saying that no such processes occur, just that most light that is only able to effect a vibrational transition is not energetic enough to effect a chemical transition. Most light that can significantly effect the rate of a reation is found in the visable range or higher (in energy).

Posted
And I use lasers to cool atoms down. Temperature is proportional to the kinetic or vibrational energy. But heat, or thermal energy, is not some separate phenomenon from this. Saying that a photon is absorbed and the energy is lost as heat implies (to me, anyway) that the photon absorption wasn't heat transfer in the first place, and that's wrong. It's all heat transfer, so that's too general a term to apply to the individual processes.

 

E=hv. I can't really say anything more than that. I was trying to illustrate to the author of this thread that once a photon is absorbed that's not necessarily the end of it, but if that energy isn't doing anything it is lost as heat. I was trying to show that while it does not have mass it is still energy. I don't understand the issue here.

 

There are very few processes for which an increase in vibrational enegy level of a molecule will provide the nessesary activation energy. Most chemical processes (processes in which electrons move about) require much larger activation energies than several thousand wavenumbers. I am not saying that no such processes occur, just that most light that is only able to effect a vibrational transition is not energetic enough to effect a chemical transition. Most light that can significantly effect the rate of a reation is found in the visable range or higher (in energy).

 

Light has a very real effect on many chemical processes. Need a list?

Posted
E=hv. I can't really say anything more than that. I was trying to illustrate to the author of this thread that once a photon is absorbed that's not necessarily the end of it' date=' but if that energy isn't doing anything it is lost as heat. I was trying to show that while it does not have mass it is still energy. I don't understand the issue here.

[/quote']

 

You were referring to vibrational energy and thermal energy as if they were two different things

Posted
You were referring to vibrational energy and thermal energy as if they were two different things

 

You can heat up molecules and make them vibrate, and you can also make the molecules vibrate, stretch, bend by exposing them to certain wavelengths and that energy eventually leaves.

 

No, I didn't. Thank God that's all that was, I was getting worried because I generally have faith in you knowing what you're talking about. Just a miscommunication.

Posted

Light has a very real effect on many chemical processes. Need a list?

 

If you can provide me with a list of chemical processes that are affected by light that excites purely vibrational/rotational transitions' date=' then sure.

 

I will accept that given enough infrared light, one can heat up a reaction to the point that you have supplied the requisite activation energy, however,....

 

 

When the photon is absorbed the vibration it causes either causes friction and is lost as heat, or it can do useful work overcomming an activation barrier or decomposing a molecule. It sort of depends on the situation.

 

emphasis mine -- reading "the vibrations it causes can do useful work overcomming an activation barrier"

 

So, i would love to hear some examples where purely vibrational events provide the activation energy or lead to decomposition.

 

I am not saying that it doesn't happen, just that I know of no examples were it does...

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