If you consider the De Broglie approach to how particles with mass behave in some circumstances then is there an essential difference? The famous two slits experiment works for em waves and beams of particles so there is quite a lot of 'waviness' in common - at least in as far as they two things can be analysed.mfb said:No, the two things have nothing in common.
I don't understand why you think this would contradict what I said.sasan said:If you are right, then Sean Carroll must be wrong in this video at Fermi Labs:
Do you have a reference to that description? I thought that the modern interpretation is that the photon is only regarded as having presence when it is interacting with a charge. Otherwise, the power flows as a wave. A "ripple" implies some location and that is a questionable model.mfb said:You can have a "ripple in the electromagnetic field" that is a photon
It is the fundamental idea of quantum field theory. Every textbook covers it.sophiecentaur said:Do you have a reference to that description?
You can have an electromagnetic field without any charges. It won't do anything interesting then, but quantum field theory without interactions is the easiest case.sophiecentaur said:I thought that the modern interpretation is that the photon is only regarded as having presence when it is interacting with a charge.
What does that mean?sophiecentaur said:Otherwise, the power flows as a wave.
A region where some ripple is: Yes. A specific location: No.sophiecentaur said:A "ripple" implies some location and that is a questionable model.
\mfb said:You can have an electromagnetic field without any charges.
Yes. It's only when there is a charge system that anything 'interesting happens'.mfb said:It won't do anything interesting then
sasan said:What I know: A ripple/wave in a field gives rise to a particle. For example, a ripple in electric field creates a photon.
Question: Is this the same principle as probability wave which when observed reveals a particle?
The OP was asking about the basic principle, rather than details of the fields involved. Sasan is not 'confusing' the two, imo. There is a lot of equivalence - even if only at the mathematical level.hilbert2 said:The electromagnetic field consists of two vector fields, while a Schrödinger wave function is a single scalar field. A massless particle like a photon can't be described with a Schrödinger wave function, you need relativistic QFT for that. Also, in relativistic quantum field theory, fermionic particles like an electron or positron are obtained by quantizing a Dirac field that is neither a scalar or a vector field, but a spinor field.
sophiecentaur said:The OP was asking about the basic principle, rather than details of the fields involved. Sasan is not 'confusing' the two, imo. There is a lot of equivalence - even if only at the mathematical level.
It's a term that is no longer used in polite circles, I believe. But the two alternative ways of looking at things are alive and well, I also believe.sasan said:what is particle-wave duality?
sophiecentaur said:I thought that the modern interpretation is that the photon is only regarded as having presence when it is interacting with a charge.
If GR gets involved, whatever happens, will happen very slooooowwwwwllllyyyy.anorlunda said:What happens when light from a star hits the surface of a neutron star?
A tad distorted, though, I would imagine. How 'thick' would its atmosphere be?mfb said:The surface of neutron stars is made out of regular atoms.
mfb said:The surface of neutron stars is made out of regular atoms.
Micrometers.sophiecentaur said:A tad distorted, though, I would imagine. How 'thick' would its atmosphere be?
I would say that the common Mathematics gives them quite a lot in common. People who feel the need for what things 'really' are, would want to make more of the distinction between them.sasan said:Dear People,
This is the bottom line:
Electromagnetic (Maxwell) waves have NOTHING to do with wave function. The only thing they have in common is the word "wave".
I hope we are all in agreement with this. Are we?
Probability waves are a mathematical concept used in quantum mechanics to describe the likelihood of finding a particle in a specific location. Electromagnetic waves, on the other hand, are a type of energy that can travel through space and are responsible for phenomena such as light, radio waves, and X-rays.
Probability waves and electromagnetic waves are both fundamental concepts in the field of physics, but they represent different aspects of the behavior of particles and energy. Probability waves describe the behavior of particles at a subatomic level, while electromagnetic waves describe the behavior of energy at a macroscopic level.
No, probability waves cannot be directly observed like electromagnetic waves. They are a mathematical concept used to describe the behavior of particles, and their effects can only be observed through experiments and measurements.
Probability waves are used in technologies such as quantum computing and cryptography, where the behavior of particles at a subatomic level can be harnessed for practical applications. Electromagnetic waves, on the other hand, are used in a wide range of technologies, including telecommunications, medical imaging, and satellite communication.
Yes, probability waves and electromagnetic waves are fundamentally different types of waves. Probability waves are a mathematical concept, while electromagnetic waves are a physical phenomenon. They have different properties and behaviors and cannot be directly compared to each other.