Spontaneous Energy Loss in Light

In summary: What drag said was that the light of the CMBR has lost a thousand times its original energy, as spacetime expanded.The light is still there, it is still light, but it has lost energy.The light of the CMBR has lost a thousand times its energy because of the expansion of the universe.That is something light can do: lose energy.So we know that light can lose energy.But what was your question there, Anil?You said[[So in reality a photons cannot loose all of it's energy?]]You were asking whether light can lose all its energy. Am I
  • #1
Les Sleeth
Gold Member
2,262
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I have a question I hope someone can help me with. Does light ever spontaneously lose energy? What I mean is, would, say, an infrared wave be traveling along and suddenly shift to microwave radiation, and maybe later to a radio wave, without any outside influences having affected it? If external influences do cause EM to lose energy, what natural circumstances would do that?

Thanks in advance for anyone's help.
 
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  • #2
I never heard about LOSS of energy (=frequency) by a photon.
 
  • #3
Loss of energy?

Light can loose energy but it depends on the medium. Wave spontaneously doesn't loose or gain energy. If that's the case we would have radiowaves from X ray machines and Gamma rays from radio stations. Only time photons loose energy is when they collide with a particle
 
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  • #4
So I might assume then, that if the universe were to expand eternally, any light that's ever been emitted and not colliding with a particle will continue forever at the same frequency?
 
  • #5
Yeah and No! most likely

Remember tired light theory. The wavelengths of the all photons lost energy through interactions with matter en route to earth. This means that almost all photons that interact with Earth must have atleast once collided with a matter or even a particle. So it's extremely rear you find a photon not collide with a matter continuing at their original frequency. I believe you will never find a photon not come in contact with matter ever since they have been emmited. If at all a photon never comes in contact with matter it should continue to move in the same frequency that they have been emitted. But let's wait till astrophysicists tell their ideas. Matter of fact Universe is expanding and galaxies are moving farther away from each other.
 
  • #6
Greetings !
Originally posted by LW Sleeth
So I might assume then, that if the universe were to expand eternally, any light that's ever been emitted and not colliding with a particle will continue forever at the same frequency?
Compared to the Universe as a whole - yes.
BUT, to us, being inside the Universe, the
frequency of EM waves decreases due to the
Universal expansion. An example is the Cosmic
Microwave Background Radiation. Shortly
after the BB the CMBR was EXTREMELY energetic
but then as the Universe expanded the frequency
and hence energy of these waves decreased until
it reached its current microwave frequency
spectral range (and it will keep decreasing).

Live long and prosper.
 
  • #7
drag: really?

So you are saying as the universe expands the frequency decreases?
 
  • #8


Originally posted by anil
Remember tired light theory. The wavelengths of the all photons lost energy through interactions with matter en route to earth. This means that almost all photons that interact with Earth must have atleast once collided with a matter or even a particle.

Not true. It simply means that you are in moving differently than the source reference system (Doppler effect as a mathematical coordinate transformation result).
 
  • #9
Originally posted by LW Sleeth

I was thinking about that because I wonder if there are lower states of energy possible for light than that of a radio wave, and if so, what might light be like in its absolute lowest state of energy.

Obviously only speculation is possible about most of that, but I thought if light had ever been observed spontaneously dropping to a lower energy state, that might be clue. [/B]

Lower than radiowave state is still radiowave (just with lower frequency: 1000000 Hz, 60 Hz, 0.00001 Hz). No additional speculations needed.
 
  • #10
Oh...ok!

So in reality a photons cannot loose all of it's energy?
 
  • #11
Photons exist due the change in energy created when an electron changes orbitals. Likewise all photons cease to exist when they induse the reverse transition within an atom. Thus photons are pure energy, they are our conceputalization of how atoms exchange energy, this is the case for all photons. So do not attempt to consider photons without some understanding of the nature of atoms.
 
  • #12


Originally posted by anil
So in reality a photons cannot loose all of it's energy?

Nope. Energy concerves.
 
  • #13
Originally posted by Integral
So do not attempt to consider photons without some understanding of the nature of atoms.

:frown:
 
  • #14
Originally posted by Integral
So do not attempt to consider photons without some understanding of the nature of atoms.

I don't think all that is necessary. Sure, atomic transitions emit light, but that is not the only source. There is also Brehmssrahlung, which is readily understandable without the gory details of atomic physics.
 
  • #15


Originally posted by anil
So you are saying as the universe expands the frequency decreases?

Anil, this is true.

this post of yours did not get a response in the thread.
You were replying to what Drag said about some very old light that has declined in frequency and quantum energy over the years:

Drag said:
[[...the
frequency of EM waves decreases due to the
Universal expansion. An example is the Cosmic
Microwave Background Radiation. Shortly
after the BB the CMBR was EXTREMELY energetic
but then as the Universe expanded the frequency
and hence energy of these waves decreased until
it reached its current microwave frequency
spectral range (and it will keep decreasing).]]

So you said "does the frequency really decrease as space
expands" and yes indeed it does. The frequencies in the
CMBR have declined by a factor of 1000.

Space stretching out makes their wavelengths longer and
that lowers their frequency by the same factor. Space
has expanded by a factor of 1000 since those photons were emitted
and so their wavelengths are 1000 times longer and
their frequencies correspondingly lower.

That light which drag was talking about is believed to be
almost as old as the universe----having been emitted only
some 300 thousand years into its history.

interesting stuff, i think
 
  • #16


Originally posted by anil
So in reality a photons cannot loose all of it's energy?

Maybe not all, without being absorbed, but a photon can lose 999/1000 of its energy and there are
trillions of photons in the space around us which have already done that----Cosmic Microwave Background photons.

Someone already replied to this post, but in a misleading way, suggesting that a photon can NOT lose any energy because
of something called "energy conservation" but this is untrue.
They CAN lose nearly all their energy.

In principle one can lose everything but a tiny remnant like a millionth of its energy. Or even all but a billionth. This is simply with the expansion of space---not by interacting or being absorbed by anything.
 
  • #17
Originally posted by Integral
Photons exist due the change in energy created when an electron changes orbitals. Likewise all photons cease to exist when they induse the reverse transition within an atom. Thus photons are pure energy, they are our conceputalization of how atoms exchange energy, this is the case for all photons. So do not attempt to consider photons without some understanding of the nature of atoms.

Radiowaves are a form of light which is made by antennas.

Shall I not attempt to consider photons unless I have made a study of antennas?

X-rays and radiowaves are forms of light. X-rays are not made by orbital-change in atoms but by a beam of electrons hitting the wall and having to stop abruptly.

I think I must understand abrupt stopping before I try to understand light.:smile:

It seems that light has something to do with the acceleration and deceleration of charge---electrons in particular.

Changes in momentum---maybe there are changes in momentum inside atoms when they emit and absorb light.

Might be understandable in a general way without studying atoms specifically.
 
  • #18


Originally posted by marcus
The frequencies in the CMBR have declined by a factor of 1000. Space stretching out makes their wavelengths longer and
that lowers their frequency by the same factor. Space
has expanded by a factor of 1000 since those photons were emitted and so their wavelengths are 1000 times longer and
their frequencies correspondingly lower. . . . interesting stuff, i think

Is this true? I'm unfamiliar with it . . . . could you recommend something I might read to get up to speed about it? I agree, intersting stuff, to me anyway.
 
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  • #19
Originally posted by Tom
There is also Brehmssrahlung, which is readily understandable without the gory details of atomic physics.

Brehmssrahlung? . . . I'll do a Google search and read up on it.

EDIT: No hits at Google . . . is that the correct spelling?
 
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  • #20


Originally posted by marcus
So you said "does the frequency really decrease as space
expands" and yes indeed it does. The frequencies in the
CMBR have declined by a factor of 1000.

Space stretching out makes their wavelengths longer and
that lowers their frequency by the same factor. Space
has expanded by a factor of 1000 since those photons were emitted
and so their wavelengths are 1000 times longer and
their frequencies correspondingly lower.
Wait, just only 1000 times?? 13billion lightyears radius that was once singularity, expanded just 1000 times?
And, if even photon looses energy due to expansion, then anything should loose energy to expansion. Or, even, which is first, expansion causing loss of energy, or loss (dissipation) of energy causing expansion?

LW, google for bremsstrahlung
 
  • #21


Originally posted by marcus
Maybe not all, without being absorbed, but a photon can lose 999/1000 of its energy and there are
trillions of photons in the space around us which have already done that----Cosmic Microwave Background photons.

Someone already replied to this post, but in a misleading way, suggesting that a photon can NOT lose any energy because
of something called "energy conservation" but this is untrue.
They CAN lose nearly all their energy.

In principle one can lose everything but a tiny remnant like a millionth of its energy. Or even all but a billionth. This is simply with the expansion of space---not by interacting or being absorbed by anything.

Incorrect. Light can not lose its energy without interaction with something. Energy and momentum must conserve.

I think, Marcus misunderstands how energy transforms from one reference system to another (coordinate transformation results in what we label as Doppler shift).
 
  • #22


Originally posted by Alexander
Incorrect. Light can not lose its energy without interaction with something. Energy and momentum must conserve.

I think, Marcus misunderstands how energy transforms from one reference system to another (coordinate transformation results in what we label as Doppler shift).

Heh heh
The cosmological redshift is not a Doppler shift
I am pretty sure you misunderstand from the things you keep
saying.

The "coordinate transformation" you refer to is probably
a Lorentz transformation.

The "Doppler shift" formula resulting from that is

1+z = sqrt [(1+beta)/(1-beta)]

This is correct in the context of Special Relativity---as the doppler shift resulting from relative radial velocity beta.

But you would be laughed at on Usenet for suggesting that formula be applied to the cosmological redshift.

You might like to read some threads on sci.physics.research about this very misconception---a lot of people have it including, apparently, yourself. A google search should do it for you.

In fact, why don't you go on use net and argue that this is the appropriate formula to use for the redshift? Treat yourself to a real argument.
 
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  • #23
Originally posted by marcus

X-rays and radiowaves are forms of light. X-rays are not made by orbital-change in atoms but by a beam of electrons hitting the wall and having to stop abruptly.

Not correct. X-rays which are used to study crystal structure ARE made by orbital change (see Mozely law). They call them K, L, M... lines. Very bright lines, by the way. They are orbital transitions of electron between inner shells. Electron states in inner shells of heavy atoms are way deep in Coulomb potential of almost unscreened (by outer electrons) strong charge of nucleus, thus their energy states are no longer in few eV but often in few KeV range. Photons originated in such orbital transitions thus also have energies in KeV range, thus we label them "x-rays".

Also, when electron beam is hitting a "brick wall" it does not stop abruptly. Instead, electron wanter in Coulomb fields of other electrons and nucleii around and begin to chenge its original direction of propagation and magnitude of its velocity (kind of randomly wandering and wiggling around). The varying electric field (between this electron and surrounding electrons and nuclei) is what we call "e/m radiation" - in the case of fast moving in the brick wall electron the electric field changes so rapidly that we call this it "x-rays".
 
  • #24


Originally posted by marcus


But you would be laughed at on Usenet for suggesting that formula be applied to the cosmological redshift.

You might like to read some threads on sci.physics.research about this very misconception---a lot of people have it including, apparently, yourself. A google search should do it for you.

In fact, why don't you go on use net and argue that this is the appropriate formula to use for the redshift? Treat yourself to a real argument.

Markus, I think your "losing energy light" hypothesis is layman crackpottery laughted at: http://www.astro.ucla.edu/~wright/tiredlit.htm

My advice - start reading good textbooks. And not just reading, (and cutting and pasting). Do homework exercises - they help way way better than just reading.

Heh heh heh...
 
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  • #25


Originally posted by Alexander
Markus, I think your "losing energy light" hypothesis is layman crackpottery laughted at: http://www.astro.ucla.edu/~wright/tiredlit.htm

My advice - start reading good textbooks. And not just reading, (and cutting and pasting). Do homework exercises - they help way way better than just reading.

Heh heh heh...

You sound as if you have completely missed the point.

If you believe in the "tired light" hypothesis and that
"tired light" explains the cosmological redshift, then it
is hopeless. Cant have a reasonable discussion.

Likewise if you believe it is a Doppler redshift.

Sorry but must cut off discussion. Bye.
 
  • #26


Originally posted by wimms
LW, google for bremsstrahlung

Thanks . . . found it.
 
  • #27


Originally posted by Alexander
http://www.astro.ucla.edu/~wright/tiredlit.htm

Interesting.

So do you say photons do not lose energy due to the universe's expansion? If so, is the low energy state of CBMR due only to it having collided with so many particles during its long journey?
 
  • #28


Originally posted by LW Sleeth
Interesting.

So do you say photons do not lose energy due to the universe's expansion? If so, is the low energy state of CBMR due only to it having collided with so many particles during its long journey?

Sleeth, Alexander's "tired light" idea is totally wacko!
Do not listen to him. He only seems to want to argue and
believe himself to be right.

Indeed the loss in energy in the CMBR is due to the expansion of the universe---best seen as having stretched out the wavelengths of CMB photons. There is a very broad consensus among cosmologists about this.

The "tired light" people must be a very small minority indeed, one never hears from them directly but only indirectly through references to the idea
 
  • #29


Originally posted by LW Sleeth
Is this true? I'm unfamiliar with it . . . . could you recommend something I might read to get up to speed about it? I agree, intersting stuff, to me anyway.

Hello Sleeth,
sorry I just noticed your reply to an earlier post of mine
I had said:

[[The frequencies in the CMBR have declined by a factor of 1000. Space stretching out makes their wavelengths longer and
that lowers their frequency by the same factor. Space
has expanded by a factor of 1000 since those photons were emitted and so their wavelengths are 1000 times longer and
their frequencies correspondingly lower. . . . interesting stuff, i think]]

And you replied to that, asking for a reference.
Ned Wright's tutorial and cosmology FAQ are the easiest places to begin, probably.

The 1000 figure (sometimes given more precisely as 1100) is the factor by which the universe has expanded since the event called "recombination" or "last scattering" which is ordinarily dated as being 300 thousand years after the beginning.

Let's say 1100 instead of 1000.

This is the same as 1+z where z is the redshift.
1+z is the ratio by which wavelengths have been stretched out and so it is the same as the factor by which space has expanded.

I have to go for the moment but will get back to this. Glad you asked. Perhaps I can find a link for you to something online.
 
  • #30


Originally posted by marcus
Sleeth, Alexander's "tired light" idea is totally wacko!
Do not listen to him. He only seems to want to argue and
believe himself to be right.

Indeed the loss in energy in the CMBR is due to the expansion of the universe---best seen as having stretched out the wavelengths of CMB photons. There is a very broad consensus among cosmologists about this.

The "tired light" people must be a very small minority indeed, one never hears from them directly but only indirectly through references to the idea

I am a little confused I think. The article Alexander referred to reasons against the tired light theory. It says:

"Tired light models invoke a gradual energy loss by photons as they travel through the cosmos to produce the redshift-distance law. This has three main problems:

* There is no known interaction that can degrade a photon's energy without also changing its momentum, which leads to a blurring of distant objects which is not observed. The Compton shift in particular does not work.
* The tired light model does not predict the observed time dilation of high redshift supernova light curves. This time dilation is a consequence of the standard interpretation of the redshift: a supernova that takes 20 days to decay will appear to take 40 days to decay when observed at redshift z=1
* The tired light model can not produce a blackbody spectrum for the Cosmic Microwave Background without some incredible coincidences. The local Universe is transparent and has a wide range of temperatures, so it does not produce a blackbody, which requires an isothermal absorbing situation. So the CMB must have come from a far away part of the Universe, and its photons will thus lose energy by the tired light effect. The plot below shows what happens if the CMB comes from z = 0.1. "

So from what Alexander is saying, it seems he disagrees with it too. Are you advocating it or disagreeing with it? Or are you saying the tired light issue has nothing to do with CMBR and the loss of energy by photons due to expansion?
 
  • #31


Hello Wimms, just saw your post. Only time for a quick answer. You replied to this frome me:

[[... "does the frequency really decrease as space
expands" and yes indeed it does. The frequencies in the
CMBR have declined by a factor of 1000.

Space stretching out makes their wavelengths longer and
that lowers their frequency by the same factor. Space
has expanded by a factor of 1000 since those photons were emitted and so their wavelengths are 1000 times longer and
their frequencies correspondingly lower.]]

In your reply you said:

Originally posted by wimms
Wait, just only 1000 times?? 13billion lightyears radius that was once singularity, expanded just 1000 times?
And, if even photon looses energy due to expansion, then anything should loose energy to expansion. Or, even, which is first, expansion causing loss of energy, or loss (dissipation) of energy causing expansion?

Since big bang there has been FAR more expansion than merely by a factor of 1100-----the factor for the CMBR.
The expansion has been by factor of 1100 since the epoch called "last scattering" or "recombination" which is when those CMB photons are thought to have been emitted.

The picture is of a clearing fog (actually hot plasma).
Above a certain temperature hydrogen gas is opaque, like the sun is opaque, because it is ionized into glowing plasma and is highly reactive with light. The electrons absorb and re-emit photons frantically.

Then as the plasma cools it suddenly becomes transparent because the neutral atoms form----no more free electrons.
The moment it becomes transparent, the photons are set free and fly essentially forever.

This cooling and transparency was reached at year 300 thousand, approx. This is the moment of origin of the CMB.

Matter behaves differently from light, in expansion. Matter too has an energy density (its mass-energy) but this falls off only as the cube------the energy simply spreads out into larger volume.
But light energy falls off as the fourth power. Because not only do there get to be fewer photons per volume but also each photon has its wavelength stretched out. This differential in the decline has an interesting effect. It changes the relative importance of matter versus light over time.

You ask which came first. The conventional view is that the expansion is a give and that the loss in CMB energy is simply one consequence of that.

Good question, thanks!
 
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  • #32
Originally posted by marcus
And you replied to that, asking for a reference.
Ned Wright's tutorial and cosmology FAQ are the easiest places to begin, probably.

Thanks, I found them and will read them today.

Originally posted by marcus
The frequencies in the CMBR have declined by a factor of 1000. Space stretching out makes their wavelengths longer and
that lowers their frequency by the same factor.

I've been known to question someone into a headache, so let me know when you've had enough. But . . .

If the expansion of space is lengthening radiation's wavelengths, doesn't this mean "space" and light are interconnected somehow? I have myself wondered if they might even be the same thing, with light simply an accentuated form of space. If space were in reality, say, some sort of polarized field that had constricted and then released to generate the big bang, and light is a ripple in that field, that might account for light's (and everything else's) polar nature, inflation, and the stretching of wavelengths as space expands.
 
  • #33
Originally posted by LW Sleeth
Thanks, I found them and will read them today.

Great! If anybody knows some other online cosmology tutorial---entry-level like this one----and similar FAQ please post the URL!

Here's a helpful animation Wright has:

http://www.astro.ucla.edu/~wright/Balloon2.html

The photons start out blue and as space expands they get longerwavelength and they turn red.
And then as space recontracts they turn shorterwavelength and are colored blue again---the coloring is just an artificial way of
diagramming the change. Neat animation---movie of the universe.

Wright's isn't perfect or complete. His professor salary and research grants pay him to do other kinds of work--his tutorial is volunteer work, labor-of-love.

someone could make it a lot better if they could get a grant just for the purpose of creating a great online (un-popularizing) introduction to cosmology.

Wright will leave you with various confusions and missing pieces of the puzzle but it is still a wonderful start!


Originally posted by LW Sleeth

If the expansion of space is lengthening radiation's wavelengths, doesn't this mean "space" and light are interconnected somehow? I have myself wondered if they might even be the same thing, with light simply an accentuated form of space. If space were in reality, say, some sort of polarized field that had constricted and then released to generate the big bang, and light is a ripple in that field, that might account for light's (and everything else's) polar nature, inflation, and the stretching of wavelengths as space expands.

Deep question. Perhaps everything is connected to space because it HAPPENS in space. Space is, I guess, sort of defined by all the geometric relations between things.

In particular, the propagation of light is connected to space because it happens in that arena----no need for extra rubberbands or little wires to interconnect the two any further. IMHO. :smile:

Thought experiment: You and I discover an experimental place outside the universe where space is not expanding. We take a laser there and measure how far a flash of light can travel in a year. Maybe we put a mirror out a ways and have the pulse
fly to the mirror and back. We see that the pulse comes back with the same frequency and wavelegth it started out with.

Then we return to our real universe and set up the experiment putting the mirror intially the same distance away. what do we see? Does the pulse take longer to return? Is its wavelength lengthened when it gets back? If so how did that happen?

This is only a thought experiment because the expansion of space on a timescale of a year is way too slight to observe!

********

I do know that if space were eventually to begin contracting (as it does in some models) then the CMB which is now so cold would get so hot after a while that it would burn us up. It would go from present long-wavelength photons back to short wavelength sort of like sunlight, some even visible light, some infrared, some UV etc. Maybe this is a good picture of how expanding and contracting space changes the wavelengths of CMB photons.

Have fun. I cannot answer all the questions that you come up with, by a long shot! But they so far cause no sign of headache.
 
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  • #34
Originally posted by marcus
I cannot answer all the questions that you come up with, by a long shot! But they so far cause no sign of headache.

I think you better get your aspirin ready. :wink:

I have a couple of more questions . . . I'll do the easy one first. I read Linder's FAQs first since it was shortest, and in it he brought up something I have been curious about. He says:

"What is meant by the edge of the universe where velocities reach the speed of light? There are a number of concepts put together in this question. By edge of the universe cosmologists mean the edge of the observable universe or the horizon. Just like on Earth the fact that you cannot see past the horizon doesn't mean there's nothing past there! (See the next question for more details.) This edge is equivalent to the distance light can travel in a time equal to the age of the universe."

Although he says what the edge means, he doesn't say what constitutes the edge. In other words, is the edge considered the the furthest reaches of matter (i.e., stars, nebula, etc.)? Or does it refer to how far light might have traveled beyond the matter it radiated from? If the edge is determined by the expansion of matter, could it be that any of it reaches the velocity of light? Finally, if it is light, then is light creating space? Or is space seen as expanding ahead of or with matter and/or light?

Originally posted by marcus
Deep question. Perhaps everything is connected to space because it HAPPENS in space. Space is, I guess, sort of defined by all the geometric relations between things.

In particular, the propagation of light is connected to space because it happens in that arena----no need for extra rubberbands or little wires to interconnect the two any further. IMHO.

I understand this is the prevalent view, but it doesn't make sense to me (I also know that a lot of things in physics are counter-intuitive but nonetheless true).

It doesn't make sense because of the mainly inviolable team of cause and effect. In virtually every other situation where an action consistantly results in a specific effect, we assume there is a relationship between the two. So, if space expands and EM's wavelength consequently stretches, that normally would mean there is some sort of causal relationship between the two. Right? Of course, it could be that aging EM would stretch whether or not the universe expands, but then we are back to the tired light theory. That is why I have thought space may be the whole ball of wax -- light, gravity, energy, expansion, matter -- all of it manifested potentials of a polarized field we call "space."

Originally posted by marcus
Thought experiment: You and I discover an experimental place outside the universe where space is not expanding. We take a laser there and measure how far a flash of light can travel in a year. Maybe we put a mirror out a ways and have the pulse
fly to the mirror and back. We see that the pulse comes back with the same frequency and wavelength it started out with.

Then we return to our real universe and set up the experiment putting the mirror intially the same distance away. what do we see? Does the pulse take longer to return? Is its wavelength lengthened when it gets back? If so how did that happen?

Well, according to what I understand about light speed, it should take the same amount of time for the pulse to return (assuming both pulses traveled in a vacuum), but according to what you are saying about light and expansion, the pulse inside the universe should return lengthened because during its travels the universe was expanding. As for how it happens, I don't know, but I do have my little theory I mentioned above.
 
  • #35


Originally posted by marcus
Sleeth, Alexander's "tired light" idea is totally wacko!
Do not listen to him. He only seems to want to argue and
believe himself to be right.


Markus, please apologise for associating this idea with me.

As you can clearly see from my post about "tired light" it was to show you that YOUR idea of "stretched photons" is wrong (as you said - totally wacko).

So, apologise for putting words I did NOT say in my mouth, ok? And don't do that again. PF is not the right place for personal attacks.
 
<h2>1. What is spontaneous energy loss in light?</h2><p>Spontaneous energy loss in light refers to the phenomenon where light particles, also known as photons, lose energy as they travel through a medium or interact with other particles. This can occur through various processes such as scattering, absorption, and emission.</p><h2>2. What causes spontaneous energy loss in light?</h2><p>The main cause of spontaneous energy loss in light is the interaction between photons and matter. When photons encounter particles in a medium, they can be absorbed or scattered, leading to a decrease in their energy. Additionally, spontaneous emission can occur when excited particles release energy in the form of photons.</p><h2>3. How does spontaneous energy loss affect the behavior of light?</h2><p>Spontaneous energy loss can alter the behavior of light in several ways. It can cause a change in the direction of light through scattering, or a decrease in its intensity through absorption. It can also lead to the emission of new photons with lower energy, resulting in a change in the wavelength of light.</p><h2>4. Is spontaneous energy loss in light always undesirable?</h2><p>No, spontaneous energy loss in light can have both positive and negative effects. In some cases, it can be harnessed for useful purposes, such as in fluorescence and laser technology. However, in other cases, it can lead to a decrease in the efficiency of light-based devices and systems.</p><h2>5. How can spontaneous energy loss in light be minimized?</h2><p>To minimize spontaneous energy loss in light, various techniques can be employed depending on the specific situation. For example, using materials with low absorption coefficients can reduce the amount of energy lost through absorption. Additionally, controlling the environment and temperature can also help minimize spontaneous energy loss. In some cases, advanced technologies such as metamaterials can also be used to manipulate the behavior of light and reduce energy loss.</p>

1. What is spontaneous energy loss in light?

Spontaneous energy loss in light refers to the phenomenon where light particles, also known as photons, lose energy as they travel through a medium or interact with other particles. This can occur through various processes such as scattering, absorption, and emission.

2. What causes spontaneous energy loss in light?

The main cause of spontaneous energy loss in light is the interaction between photons and matter. When photons encounter particles in a medium, they can be absorbed or scattered, leading to a decrease in their energy. Additionally, spontaneous emission can occur when excited particles release energy in the form of photons.

3. How does spontaneous energy loss affect the behavior of light?

Spontaneous energy loss can alter the behavior of light in several ways. It can cause a change in the direction of light through scattering, or a decrease in its intensity through absorption. It can also lead to the emission of new photons with lower energy, resulting in a change in the wavelength of light.

4. Is spontaneous energy loss in light always undesirable?

No, spontaneous energy loss in light can have both positive and negative effects. In some cases, it can be harnessed for useful purposes, such as in fluorescence and laser technology. However, in other cases, it can lead to a decrease in the efficiency of light-based devices and systems.

5. How can spontaneous energy loss in light be minimized?

To minimize spontaneous energy loss in light, various techniques can be employed depending on the specific situation. For example, using materials with low absorption coefficients can reduce the amount of energy lost through absorption. Additionally, controlling the environment and temperature can also help minimize spontaneous energy loss. In some cases, advanced technologies such as metamaterials can also be used to manipulate the behavior of light and reduce energy loss.

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