That's not actually true. Not in vacuum. These interactions can affect how a particle interacts with another particle, but you'll never get "friction" in vacuum.Mentz114 said:and also affect the trajectories of particles ( see Feynman diagrams).
Friction would imply that an object in motion would be slowed down and eventually come to rest. But since the vacuum state is Lorentz invariant, there is no preferred rest frame, and "coming to rest" is meaningless.anubodh said:but even then there should be a frictional force all round the universe)
Affecting the trajectories of particles would imply that an object could exchange momentum with the vacuum. But the vacuum state is translation invariant, so its energy-momentum vector is zero, and this cannot be changed by interaction with a particle.Mentz114 said:But at the atomic/sub-atomic level they can cause spectral lines to split ( see the Lamb effect) and also affect the trajectories of particles ( see Feynman diagrams).
K^2 said:So for every electron that pops up into existence, there is a positron, so that the net electric field is zero, and there is no net interaction.
Bill_K said:Friction would imply that an object in motion would be slowed down and eventually come to rest. But since the vacuum state is Lorentz invariant, there is no preferred rest frame, and "coming to rest" is meaningless.
Affecting the trajectories of particles would imply that an object could exchange momentum with the vacuum. But the vacuum state is translation invariant, so its energy-momentum vector is zero, and this cannot be changed by interaction with a particle.
Since there are quantum fluctuations popping in and out of existenceSaying it fluctuates is like saying Schrodinger's cat rapidly fluctuates between being alive and dead. The vacuum state is Lorentz invariant. It appears the same in all {inertial} reference frames.
It's quite picturesque to imagine the vacuum state as a "boiling cauldron of activity", but it's not - it's simply a static superposition of states having different particle numbers.
Thanks for pointing this out. 'Trajectories' is not a good choice of word for the perturbative loop calculation ( what does that mean, exactly ?)Bill_K said:Affecting the trajectories of particles would imply that an object could exchange momentum with the vacuum. But the vacuum state is translation invariant, so its energy-momentum vector is zero, and this cannot be changed by interaction with a particle.
And that's why it's just an analogy. Naty1's reply points out the actual physics of it. I think I oversimplified it too much in attempt to make it more intuitive.ChrisVer said:However doesn't that imply there would be no vacuum polarization?
anubodh said:Since there are quantum fluctuations popping in and out of existence then there should be an friction in the space though negligible(i know that they disappear in less than planks time but even then there should be a frictional force all round the universe)
These fluctuations present great mathematical difficulties, and also they are not of physical importance. They get bypassed when one uses the Heisenberg picture, and one is then able to concentrate on quantities that are of physical importance.
Friction in empty space, also known as quantum friction, is a phenomenon in which particles experience a resistance or drag when moving through the vacuum of space. This is believed to be caused by quantum fluctuations, or tiny fluctuations in energy fields, that constantly occur in empty space.
The concept of friction in empty space is based on the theory that quantum fluctuations can give rise to virtual particles, which can then interact with real particles and cause them to experience a resistance or drag. This effect is known as the Casimir effect, and it is the basis for the idea of quantum friction in empty space.
Yes, there have been experiments conducted to observe the effects of quantum friction in empty space. One notable example is the Casimir force, which has been measured and confirmed by multiple experiments. However, directly observing the effects of quantum fluctuations on particles is still a challenging task for scientists.
If the existence of friction in empty space is confirmed, it could have significant implications for our understanding of the laws of physics. It could also have practical applications, such as in the development of new technologies for energy conversion or propulsion systems.
There is currently no consensus among scientists about the existence of friction in empty space. While some theories and experiments suggest its existence, others remain skeptical and argue that the observed effects could have alternative explanations. Further research and experimentation are needed to reach a definitive conclusion.