Understanding Quantization of Energy: Can We Produce EM Waves of Any Energy?

In summary: For unbound systems, the energy of a photon is continuous and can take on any value, as long as it satisfies E=hf. So while the energy levels of bound systems are quantized, there is still a continuous range of possible photon energies in the universe. In summary, the energy levels of bound systems are quantized, but there is still a continuous range of possible photon energies in the universe. The equation E=hf can be used to calculate the energy of a photon, but there may be practical limits to the range of energies that can be produced. Additionally, the energy levels of bound systems can be perturbed, allowing for the production of photons of arbitrary energy.
  • #1
Cheman
235
1
Quantization of energy...

We say that electrons have set energy levels, and certain energies they cannot possesses whilst in a certain atom. Is it still possible to produce photons / EM waves of any energy we desire? I mean, by looking at the equation E = hf it would appear we can - if we put in any value for f we can get any value for E. (obviously this would mean not being pedantic and talking about -ve numbers, etc. :wink: ) We can't just say "yeh we found out a wave with this frequency has this energy - but it doesn't exist!" - can we?

Thanks in advance. :smile:
 
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  • #2
Cheman said:
We say that electrons have set energy levels, and certain energies they cannot possesses whilst in a certain atom. Is it still possible to produce photons / EM waves of any energy we desire?

In principle, yes, though there might be practical upper and lower limits.


"yeh we found out a wave with this frequency has this energy - but it doesn't exist!" - can we?

The energy levels of a quantum system are quantized, but in general, the solutions can be perturbed by small amounts so that the energy levels all shift a bit, allowing for the production of a photon of arbitrary energy. Alternatively, you can just exploit the Doppler effect and start moving with respect to the photon or emitting atom. Depending on your velocity, you'll observe a slightly different wavelength for the photon.
 
  • #3
I think the point is that E=hf is not the be all and end all of describing photons. Instead, we've got

[tex]\hat{H}\psi=E\psi[/tex]

for a bound system, such as an atom, you'll find that you get discrete values of E, instead of a continuous range.
 
  • #4
masudr said:
I think the point is that E=hf is not the be all and end all of describing photons. Instead, we've got

[tex]\hat{H}\psi=E\psi[/tex]

for a bound system, such as an atom, you'll find that you get discrete values of E, instead of a continuous range.

My point is that this fact doesn't put restrictions on a continuous range of possible photons in the universe, it just restricts them for a given atom/molecule.
 
  • #5
SpaceTiger said:
My point is that this fact doesn't put restrictions on a continuous range of possible photons in the universe, it just restricts them for a given atom/molecule.

Yes of course, although when the orignal poster speaks of "energy levels" he/she almost invariably refers to an atom or molecule, or some other kind of bound system.
 

Related to Understanding Quantization of Energy: Can We Produce EM Waves of Any Energy?

1. What is quantization of energy?

Quantization of energy is the concept that energy can only exist in discrete amounts, rather than being continuous. This means that energy cannot be divided into infinitely small units, but rather comes in specific, quantized units.

2. How does quantization of energy relate to electromagnetic waves?

Electromagnetic (EM) waves are a form of energy that also follow the principle of quantization. The energy of an EM wave is directly proportional to its frequency, and can only exist in specific, quantized amounts based on the frequency of the wave.

3. Can we produce EM waves of any energy?

No, we cannot produce EM waves of any energy. As mentioned earlier, the energy of an EM wave is quantized and can only exist in specific amounts determined by its frequency. While we can manipulate the frequency of EM waves, we cannot produce them with arbitrary energy levels.

4. How do scientists manipulate the energy of EM waves?

Scientists can manipulate the energy of EM waves by changing their frequency. This can be achieved through various methods such as changing the properties of the source producing the waves, or by using devices like filters or amplifiers to adjust the frequency of the waves.

5. Why is understanding quantization of energy important for producing EM waves?

Understanding quantization of energy is important for producing EM waves because it helps us understand the limitations and possibilities of manipulating their energy levels. It also allows us to accurately measure and predict the energy of EM waves, which is crucial in many applications such as communication and medical imaging.

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