So light has dual nature but I was wondering

In summary, light behaves neither like particles nor like waves, but has its own unique nature described by a wavefunction. It is not possible for light to be the size of a tennis ball and still exhibit its characteristic behavior. This is because everything at that size, including electrons and atoms, also share this non-particle non-wave nature. Quantum field theory, rather than a wave function, is the appropriate framework for describing light and its behavior. Additionally, it is not possible to define a position operator for photons in a naive way.
  • #1
Abidal Sala
30
0
So if light acts like waves when interacting with huge objects and acts like regular particles when interacting with very small bodies like atoms and electrons.. now I know this might sound silly, but what if the photons were to be in the size of a tennis ball, and the electrons also relatively huge, will we still witness light to be acting like a regular particle ? like the electrons absorbing photons individually? or will light act like a wave?
 
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  • #2
First I'm going to correct one of your assumptions: light always acts the same, and it's neither like particles nor like waves. It's something else entirely, described by a wavefunction.

On to your question, it is really meaningless, because there is no way light would be that size. It behaves the way it does because it's that small. In fact, everything that size behaves the same way. Electrons, protons, photons, neutrinos, and even bigger stuff, atoms, and all of that, behaves exactly like light, with the weird non-particle non-wave nature.

And also, since you are made of all of that, you, too, possesses these properties of non-particleness and non-waveness. It's just that there are so many non-particles non-waves making you up that these effects mostly disappear for all practical purposes.
 
  • #3
Also this view must be corrected since particularly photons, massless quanta of a vector quantum field cannot be described by a wave function but by a quantum field. The reason is that they are very easily created (e.g., bremsstrahlung by accelerated charges or in annihilation of a particle-antiparticle pair, etc. etc.) or destroyed (e.g., in the photoelectric effect, pair creation at a heavy nucleus,...). Thus one has to use quantum field theory which easily takes account of creation and destruction processes.

A quantum mechanical state behaving most closely like a classical electromagnetic wave are the socalled "coherent state", which are a special superposition of states of arbitrary photon numbers (including also the vacuum, i.e., the state with no photons), i.e., they don't have a well-defined photon number at all.

Also one cannot define in a naive way a position operator for photons. See Arnold Neumaier's physics FAQ on this quite subtle point of relativistic quantum theory of massless quanta:

http://arnold-neumaier.at/physfaq/topics/position.html
 

1. What is the dual nature of light?

The dual nature of light refers to the fact that light can exhibit both wave-like and particle-like behavior. This means that light can behave as a wave, with properties such as diffraction and interference, but it can also behave as a particle, with properties such as momentum and energy.

2. How was the dual nature of light discovered?

The dual nature of light was first proposed by physicist Thomas Young in the early 1800s through his double-slit experiment, which showed that light could exhibit interference patterns similar to waves. This was further supported by Albert Einstein's explanation of the photoelectric effect in 1905, which showed that light also behaves as particles called photons.

3. Can all types of light exhibit dual nature?

Yes, all types of light, including visible light, infrared radiation, ultraviolet radiation, and even radio waves, can exhibit the dual nature of light. This is because all forms of light are ultimately made up of individual particles of energy, called photons, which can exhibit both wave-like and particle-like behavior.

4. How does the dual nature of light impact our understanding of the universe?

The discovery of the dual nature of light has had a significant impact on our understanding of the universe. It has allowed us to better understand the behavior of light and electromagnetic radiation, which is essential for various technologies such as lasers and telecommunications. It has also helped us to develop a deeper understanding of quantum mechanics and the fundamental nature of matter and energy.

5. Can the dual nature of light be explained by one theory?

Currently, the dual nature of light is best explained by the theory of quantum mechanics, which describes the behavior of particles at the subatomic level. However, there are still many unanswered questions and ongoing research in this area, and it is possible that future theories could provide a more comprehensive explanation of the dual nature of light.

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