My view is this:thenewmans said:What are your views?
But does QFT entirely incorporates QM? For example, what about the particle-position operator in QFT?tim_lou said:I don't think there is anything, as QFT entirely incorporates SR.
Can you explain why?thenewmans said:But I am not equipped to digest it.
I would not say that SR depends on locality and causality. I would say that SR depends on invariance with respect to Lorentz transformations. In this sense, nonlocality and violation of causality may still be compatible with SR. In particular, motion faster than light, by itself, is compatible with SR.thenewmans said:My understanding is that SR depends on locality and causality. So doesn’t QM contradict SR?
No. I mean a relativistic generalization of the particle-position operator in nonrelativistic QM.tim_lou said:When you say particle-position operator, do you mean ψ and ψ† ?
Demystifier said:Can you explain why?
I see. In this case, you may visit my blog, in which some main ideas of quantum mechanics and its Bohmian interpretation are explained for non-physicists in terms of everyday analogies.thenewmans said:Demystifier, I'm not a QM guy. I'm not even a physics guy. I just like trying to understand this stuff. The math and Greek letters are beyond me. If I can't type it in Excel, I'm lost. ;) Maybe some day.
Demystifier said:I see. In this case, you may visit my blog, in which some main ideas of quantum mechanics and its Bohmian interpretation are explained for non-physicists in terms of everyday analogies.
Demystifier said:I would not say that SR depends on locality and causality. I would say that SR depends on invariance with respect to Lorentz transformations. In this sense, nonlocality and violation of causality may still be compatible with SR. In particular, motion faster than light, by itself, is compatible with SR.
Only if you make some additional assumptions. The assumption of the Lorentz invariance alone does not impose causality and locality. Show me any concrete derivation of causality and locality and I will tell you what are the underlying additional assumptions.QuantumDevil said:I though that invariance with respect to Lorentz transformation imposed causality and locality
Demystifier said:Only if you make some additional assumptions. .
As I already said, show me any concrete derivation and I will ...QuantumDevil said:Such as?
The main difference between Special Relativity (SR) and Quantum Mechanics (QM) is the scale at which they operate. SR deals with objects at a macroscopic level, while QM deals with objects at a microscopic level. SR explains the behavior of objects moving at high speeds, while QM explains the behavior of subatomic particles.
Special Relativity states that the speed of light is constant in all frames of reference. This means that no matter how fast an observer is moving or in which direction, the speed of light will always be measured as the same value. This is a fundamental principle of SR and has been confirmed by numerous experiments.
The wave-particle duality principle is a key concept in QM that states that particles can exhibit both wave-like and particle-like behavior. This means that particles can have properties of both waves, such as interference patterns, and particles, such as having a specific location and momentum. This principle helps to explain many phenomena observed in QM.
While SR and QM may seem to contradict each other, they are both well-established theories that accurately describe different aspects of the universe. SR explains the behavior of objects at high speeds, while QM explains the behavior of particles at a microscopic level. Both theories have been extensively tested and have been shown to be valid within their respective domains.
One proposed theory is the theory of Quantum Gravity, which aims to merge the principles of QM and SR to create a more comprehensive understanding of the universe. Another theory is the Many-Worlds Interpretation, which suggests that every possible outcome of an event exists in a different universe. However, these theories are still being researched and are not yet widely accepted by the scientific community.