How can energy be quantized with E=hv

In summary, the concept of energy quantization was first introduced by Planck to explain the relationship between energy and frequency in electromagnetic radiation. This means that the energy of a photon is directly proportional to its frequency, with the constant of proportionality being Planck's constant. While a "free" photon can have any energy, a confined photon's energy spectrum is discrete. This idea was used to solve the problem of the ultraviolet catastrophe in black-body radiation. However, this does not change the spectrum of allowed frequencies, but rather the ease of producing radiation at different frequencies.
  • #1
mahela007
106
0
I don't understand how Planck's equation can state that energy is quantized.
in E = hv where E = energy of the photon h Planck's constant and v=frequency how can E have only discrete amounts?

plancks constant is .. well.. a constant but isn't frequency a constantly varying or Infinitely variable quantity? If so, how can E have only certain values?

(In the book "Advanced chemistry by Raymond Chang" it says that energy can come in packets which have energies of hv, 2hv, 3hv and so on... I'm having trouble understanding this as well..)
thanks.
 
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  • #2
mahela007 said:
I don't understand how Planck's equation can state that energy is quantized.
in E = hv where E = energy of the photon h Planck's constant and v=frequency how can E have only discrete amounts?

plancks constant is .. well.. a constant but isn't frequency a constantly varying quantity? If so, how can E have only certain values?

(In the book "Advanced chemistry by Raymond Chang" it says that energy can come in packets which have energies of hv, 2hv, 3hv and so on... I'm having trouble understanding this as well..)
thanks.

There are two innovative things: the energy quantization hypothesis (radiation and absorption by quanta) and the relationship between the quanta energy and frequency E = hv. The latter just implies that this relationship should be used in statistical treatment together with the the energy quantization hypothesis.
 
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  • #3
Bob_for_short said:
There are two innovative things: the energy quantization hypothesis (radiation and absorption by quanta) and the relationship between the quanta energy and frequency E = hv. The latter just implies that this relationship should be used in statistical treatment together with the the energy quantization hypothesis.

umm... I don't understand..
 
  • #4
mahela007 said:
I don't understand how Planck's equation can state that energy is quantized.
in E = hv where E = energy of the photon h Planck's constant and v=frequency how can E have only discrete amounts?

plancks constant is .. well.. a constant but isn't frequency a constantly varying or Infinitely variable quantity? If so, how can E have only certain values?

(In the book "Advanced chemistry by Raymond Chang" it says that energy can come in packets which have energies of hv, 2hv, 3hv and so on... I'm having trouble understanding this as well..)
thanks.

It means that electromagnetic radiation of frequency v can only come in "packets" of energy hv. Those packets are called photons. So what is quantized here, is the energy transmitted by electromagnetic radiation of frequency v. Of course, "electromagnetic radiation" can have any kind of energy, because, as you point out, frequencies are continuous. But for a *given frequency*, the energy exchange can only take place in jumps of hv.
 
  • #5
In relation to OP's question:

Is there a fundamental emergence of the quantization of electromagnetic energy? I can see why a "confined" electron has quantized energies (this just comes from the requirement that the electron wave must be fitted in the box) but unlike a photon, a free electron can have any energy ...

Why does a "free" photon have to have quantized energies? (is there a theoretical justificiation for this?)
 
  • #6
In order to obtain the quantum relationship E = hv, one can consider EMF amplitude for a certain harmonic. This amplitude obeys an oscillator equations. Quantum oscillator levels are quantized and the energy differences are just n*hv.

Such oscillators are permanently coupled to charges. When an electron changes its level in an atom, the energy difference is given to/taken from a resonant oscillator => emission/absorption of a photon with E = E2 - E1 = hv12 = ћω12.

When many similar atoms make a transition together (in a laser), the resulting filed is a beam of many photons.
 
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  • #7
You have to be careful how you interpret the expression "photon energy is quantized". In fact, the spectrum of allowed energies of a free photon *is* continuous--i.e., a free photon *can* have any energy, whereas a confined photon's energy spectrum is discrete. This, however, is consistent with photon energy being quantized!

As previous posters have noted, the literal meaning of "photon energy is quantized" is nothing more than the fact that a given photon's energy is directly proportional to its frequency, the constant of proportionality being Planck's constant:

[tex]E = h \nu[/tex]

But the question, "how is a photon's energy related to its frequency?" is a *different* question than the question, "what are the allowed energies of a photon?" The latter question depends on the physical situation; generally speaking, a "free" particle (meaning, approximately, that the particle is not "confined" to a limited space) has a continuous energy spectrum (meaning a continuous spectrum of allowed frequencies), whereas a "confined" particle (meaning, approximately, that it is not allowed to be anywhere in space, but only allowed to be in a certain compact region--this might also be expressed as the particle being in a "bound state") has a discrete energy spectrum. For example, electrons bound in atoms have a discrete energy spectrum ("energy levels"), whereas free electrons have a continuous energy spectrum, just like free photons.

Historically, the "quantum hypothesis" was first put forward by Planck in order to solve the problem of the http://en.wikipedia.org/wiki/Ultraviolet_catastrophe" [Broken] in black-body radiation. Adding the quantum hypothesis, in that case, did *not* change the spectrum of allowed frequencies for black-body radiation--that remained continuous. What the quantum hypothesis did was change how hard it was to produce radiation of a given frequency; the old, classical assumption had been that all frequencies, even very, very high ones, were equally easy to radiate, whereas under the quantum hypothesis, low frequencies were far easier to radiate than high frequencies. So even in the original case, photons being quantized did *not* imply a discrete energy spectrum.
 
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  • #8
Just to make things clear:

Suppose you have some electromagnetic pulse at frequency v, with a set amount of total energy E. The conjecture is that the energy is divided into quantized packets of energy: the photons. Each photon or energy packet carries an energy E_photon = hv. So total amount of energy packets or photons is simply E_total/E_photon.

If we now increase the energy, then the only way to do this is to add another energy package. So we can have an energy of E_total and of E_total + hv, but nothing in between. This is the quantization what people refer to. We cannot have some electromagnetic field pulsating at a frequency v and containing some arbitrary energy E. The energy is quantized in terms of hv.

You can punch a few holes in this story, but the main idea should be clear... ;)
 
  • #9
PeterDonis said:
You have to be careful how you interpret the expression "photon energy is quantized". In fact, the spectrum of allowed energies of a free photon *is* continuous--i.e., a free photon *can* have any energy, whereas a confined photon's energy spectrum is discrete. This, however, is consistent with photon energy being quantized!

As previous posters have noted, the literal meaning of "photon energy is quantized" is nothing more than the fact that a given photon's energy is directly proportional to its frequency, the constant of proportionality being Planck's constant:

[tex]E = h \nu[/tex]

But the question, "how is a photon's energy related to its frequency?" is a *different* question than the question, "what are the allowed energies of a photon?" The latter question depends on the physical situation; generally speaking, a "free" particle (meaning, approximately, that the particle is not "confined" to a limited space) has a continuous energy spectrum (meaning a continuous spectrum of allowed frequencies), whereas a "confined" particle (meaning, approximately, that it is not allowed to be anywhere in space, but only allowed to be in a certain compact region--this might also be expressed as the particle being in a "bound state") has a discrete energy spectrum. For example, electrons bound in atoms have a discrete energy spectrum ("energy levels"), whereas free electrons have a continuous energy spectrum, just like free photons.

Historically, the "quantum hypothesis" was first put forward by Planck in order to solve the problem of the http://en.wikipedia.org/wiki/Ultraviolet_catastrophe" [Broken] in black-body radiation. Adding the quantum hypothesis, in that case, did *not* change the spectrum of allowed frequencies for black-body radiation--that remained continuous. What the quantum hypothesis did was change how hard it was to produce radiation of a given frequency; the old, classical assumption had been that all frequencies, even very, very high ones, were equally easy to radiate, whereas under the quantum hypothesis, low frequencies were far easier to radiate than high frequencies. So even in the original case, photons being quantized did *not* imply a discrete energy spectrum.

I think you have provided the most careful answer, and it was helpful...
So a free photon can have 'any' energy (because the spectrum variable f is essentially continuous), so the energy of an unconfined photon is in no way restricted...

And the fact that electromagnetic radiation is carried by packets of energy, i.e, photon is analogous to the electric current being carried by electrons.
 
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  • #10
mahela007 said:
I don't understand how Planck's equation can state that energy is quantized.
in E = hv where E = energy of the photon h Planck's constant and v=frequency how can E have only discrete amounts?

plancks constant is .. well.. a constant but isn't frequency a constantly varying or Infinitely variable quantity? If so, how can E have only certain values?

(In the book "Advanced chemistry by Raymond Chang" it says that energy can come in packets which have energies of hv, 2hv, 3hv and so on... I'm having trouble understanding this as well..)
thanks.

A free field has fixed periodicity T=1/v. Thus only frequencies v, 2v, 3v, ... nv are allowed and the energy come in packets hv, 2hv, 3hv, ... nhv, through the Planck constant.
 
  • #11
So the basic idea is something like this.
If there is a EM wave for a certain frequency (v), it will be made up of packets , each of which have a energy of hv.
Am I right?
 
  • #12
hmmm, this kind of remind me of quanta, an explanation for the ridiculous theory "an body emits energy at any frequency" which will result in emition of infinite energy...
So a give atom or w/e will absorb and re-emitt the photons at a certain spectrum...
Am i on the right track? I' am a bit comfused after reading this...
 
  • #13
Confusion is a natural result of quantum theory.. (Sorry I can't give a more helpful answer)
 
  • #14
I still can't seem to understand this.
Why go though all the trouble to say energy is quantized when in fact it doesn't appear to be so.. (at least to me.)
From the above posts, here's what I understood.
Photons CAN have any energy... However, their energy is proportional to their frequency. Therefore from a light source of given frequency(say, a red light) , there are many many photons rushing out.. all of them have the same energy because they have the same frequency..

But if slightly different shade of red was produced by the light, the light would still be made of photons.. however, the photons will have a slightly different energy.

So isn't energy a continuous quantity?
 
  • #15
Here is my understanding (most likely I'm wrong), in a laser radiation of specific frenquency each quantum carry's a certain amount of energy and there is no like.. in between.
 
  • #16
mahela007 said:
From the above posts, here's what I understood.
Photons CAN have any energy... However, their energy is proportional to their frequency. Therefore from a light source of given frequency(say, a red light) , there are many many photons rushing out.. all of them have the same energy because they have the same frequency..

But if slightly different shade of red was produced by the light, the light would still be made of photons.. however, the photons will have a slightly different energy.

So isn't energy a continuous quantity?

Quantized means exactly what you've written in this case and yes energy is a continuous quantity since frequency is continuous. But that does not change the the fact that photons of a specific frequency all have the same energy which is a quantum mechanical result (in fact it was the FIRST result in what we now call QM), there is no classical "justification" for why this must is true, remember that there is no such thing as a "classical photon".

Note also that this has important consequences not only for lasers etc but also for ordinary light, the fact that light is quantized changes its statistical properties (e.g. the distribution of light emitted by a source of a given temperature) quite profoundly which is why Planck was able to solve the UV paradox when he introduced quantization.
 
  • #17
I see...
But how does it apply to ordinary lights? interference?
 
  • #18
mahela007 said:
So the basic idea is something like this.
If there is a EM wave for a certain frequency (v), it will be made up of packets , each of which have a energy of hv.
Am I right?

Yes.
 
  • #19
mahela007 said:
I still can't seem to understand this.
Why go though all the trouble to say energy is quantized when in fact it doesn't appear to be so.. (at least to me.)
From the above posts, here's what I understood.
Photons CAN have any energy... However, their energy is proportional to their frequency. Therefore from a light source of given frequency(say, a red light) , there are many many photons rushing out.. all of them have the same energy because they have the same frequency..

But if slightly different shade of red was produced by the light, the light would still be made of photons.. however, the photons will have a slightly different energy.

So isn't energy a continuous quantity?

Yes. (for an unbound system).
 
  • #20
I would like to make a general comment: in many scientific disciplines, but especially in quantum mechanics, there are many "catch phrases" which are correctly and succinctly summarizing a certain property/phenomenon/event/view/... in a given context, but which are then thrown around in all generality and stated as "general truths" or "principles", especially in introductory and popularizing texts. It is my impression that they add more to confusing than anything else. "energy is quantized" is one of those catch phrases. There are many others floating around in "quantum speak". If you know what they mean exactly, then they are right, but usually one needs a much deeper understanding of quantum mechanics than is available to the reader to which one gives these "one-liners", and then they are genuinely confusing.
 
  • #21
Bravo Vanesch... you hit the nail right on the head.
Well.. as for my little problem, it's been solved. Thanks for your help.
 
  • #22
vanesch said:
I would like to make a general comment: in many scientific disciplines, but especially in quantum mechanics, there are many "catch phrases" which are correctly and succinctly summarizing a certain property/phenomenon/event/view/... in a given context, but which are then thrown around in all generality and stated as "general truths" or "principles", especially in introductory and popularizing texts. It is my impression that they add more to confusing than anything else. "energy is quantized" is one of those catch phrases. There are many others floating around in "quantum speak". If you know what they mean exactly, then they are right, but usually one needs a much deeper understanding of quantum mechanics than is available to the reader to which one gives these "one-liners", and then they are genuinely confusing.

True! Physics is done using the mathematical language. When mathematical concepts are translated in ordinary words, it is inevitable to generate misunderstandings.
 
  • #23
mahela007 said:
I don't understand how Planck's equation can state that energy is quantized.
in E = hv where E = energy of the photon h Planck's constant and v=frequency how can E have only discrete amounts?

plancks constant is .. well.. a constant but isn't frequency a constantly varying or Infinitely variable quantity? If so, how can E have only certain values?

You can build an oscillator with a constantly varying frequency but only certain frequencies can be absorbed or emitted by atoms and these are defined by the spectral lines of the atoms. This means that an atom can only absorb energy tied to fixed frequencies and the amount of energy is given by E=hv.
 
  • #24
Uli said:
plancks constant is .. well.. a constant but isn't frequency a constantly varying or Infinitely variable quantity? If so, how can E have only certain values?

The energy of a photon can have any value.

You can build an oscillator with a constantly varying frequency but only certain frequencies can be absorbed or emitted by atoms and these are defined by the spectral lines of the atoms. This means that an atom can only absorb energy tied to fixed frequencies and the amount of energy is given by E=hv.

The fact that atoms can only emit or absorb photons with some values doesn't mean photons with other values can't exist.
 
  • #25
PeterDonis said:
For example, electrons bound in atoms have a discrete energy spectrum ("energy levels"), whereas free electrons have a continuous energy spectrum, just like free photons.
What does it mean exactly? Of course it doesn't mean that you can accelerate a free photon...
 
  • #26
lightarrow said:
What does it mean exactly? Of course it doesn't mean that you can accelerate a free photon...

It means that there exist free photon states of all energies (in other words, that the energy spectrum of the free EM field is continuous).
 
  • #27
vanesch said:
It means that there exist free photon states of all energies (in other words, that the energy spectrum of the free EM field is continuous).
Thanks vanesh.
 
  • #28
really, E=hf shouldn't be thought of as a pure quantum rule. it's a way to relate frequency to energy and not a statement about any specific state or set of states in an atom. basically that equation is used once we figure out either the energy or the frequency of a transition between quantum states so that we can find the other value. no inference can be taken because of the equation.

i hope that's a little bit simpler language than the rest of the thread.
 
  • #29
burningbend said:
really, E=hf shouldn't be thought of as a pure quantum rule. it's a way to relate frequency to energy and not a statement about any specific state or set of states in an atom. basically that equation is used once we figure out either the energy or the frequency of a transition between quantum states so that we can find the other value. no inference can be taken because of the equation.
I ... almost completely agree. Not totally, because:
starting from electromagnetic (classical) Doppler shift, you can find that the em energy transforms, under a velocity boost, in a certain way, which becomes exactly E = hf under the hypothesys that the field is made of energy "packets"; the energy arriving to a detector depends on the energy of the single packet and on the number of packets arriving and this number, as the frequency, depends on the relative velocity v between source and detector.
Probably there is a simpler way to say that using 4-vectors, anyway, the simple fact that E = hf, is *almost* a prove that the field's energy comes in "packets".
 

1. What does E=hv stand for?

E=hv is a formula that represents the relationship between energy (E) and frequency (v) of a wave. It is known as the Planck-Einstein relation and is a fundamental concept in quantum mechanics.

2. How does energy being quantized with E=hv relate to quantum mechanics?

In quantum mechanics, energy is not continuous but rather exists in discrete packets called quanta. E=hv shows that the energy of a quantum is directly proportional to its frequency, meaning that the higher the frequency, the higher the energy of the quantum. This helps explain the behavior of particles at the atomic and subatomic level.

3. Can you give an example of energy being quantized with E=hv?

An example of energy being quantized with E=hv is the emission of photons from an excited atom. When an electron moves from a higher energy state to a lower one, it emits a photon with a specific frequency (v) and energy (E) according to the equation E=hv.

4. How was the concept of energy quantization discovered?

The concept of energy quantization was first introduced by Max Planck in 1900 as a way to explain the behavior of blackbody radiation. He proposed that energy is not continuous but is instead radiated in discrete packets called "quanta". This idea was later expanded upon by Albert Einstein in his work on the photoelectric effect.

5. Is the concept of energy quantization only applicable to light?

No, the concept of energy quantization with E=hv applies to all forms of energy, including matter. In fact, it is a fundamental principle in quantum mechanics and helps explain the behavior of particles at the atomic and subatomic level.

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