fxdung said:in Superconductor when energy of phonon is smaller than energy gap of Cooper pair then there is not phonon-electron interaction?
fxdung said:one could apply QFT in Condensed Matter Physics
fxdung said:I like to know both: phonon and photon
fxdung said:In QFT a photon with arbitrary energy can interact with an electron.
fxdung said:in Superconductor when energy of phonon is smaller than energy gap of Cooper pair then there is not phonon-electron interaction?
A photon with arbitrary energy can interact with a "free" electron (that is, electron that was free before the photon arrived), because the energy spectrum of the free electron is continuous. In atoms or crystal lattices, where the electrons are not free, the energy spectrum is often not continuous. But it has nothing to do with a difference between QFT and QM. In principle, both can study either free or non-free electrons. In practice, however, QFT is often applied to study scattering of elementary particles, where the asymptotic scattering states are free.fxdung said:In QFT a photon with arbitrary energy can interact with an electron.But in QM and Solid State Physics, if energy of photon smaller than energy gap of electron then photon can not interact the electron.So it seems to me there is a contradiction?
Of course there is phonon-electron interaction, first of all forming the Cooper pairs, generating a mass gap and "Anderson-Higgsing" the photon.fxdung said:But in Superconductor when energy of phonon is smaller than energy gap of Cooper pair then there is not phonon-electron interaction?
I just wanted to make clear that photons and electrons always interact. For a bound electron, however you have a finite gap between the energy of this state and of the next energy eigenstate (which may be again a bound state or also a scattering state). A single photon with an energy less than this energy difference is necessarily elastically scattered on this bound electron, i.e., it leaves the atom in the same intrinsic state as it was before but still scatters elastically. Energy-momentum conservation is then fulfilled by the scattered photon and the atom as a whole. The free center-mass motion of the atom never has a energy gap and thus can always change in an interaction with a photon of any energy.Demystifier said:A photon with arbitrary energy can interact with a "free" electron (that is, electron that was free before the photon arrived), because the energy spectrum of the free electron is continuous. In atoms or crystal lattices, where the electrons are not free, the energy spectrum is often not continuous. But it has nothing to do with a difference between QFT and QM. In principle, both can study either free or non-free electrons. In practice, however, QFT is often applied to study scattering of elementary particles, where the asymptotic scattering states are free.
QFT and QM are two theories that attempt to explain the behavior of particles at the subatomic level. While QM focuses on the behavior of individual particles, QFT takes into account the interactions between particles. At first glance, these two theories may seem contradictory, but they are actually complementary and can be used together to provide a more complete understanding of the subatomic world.
One example is the concept of locality. In QM, particles can be in multiple places at once, while in QFT, particles are confined to specific locations in space and time. Another example is the treatment of particles as waves in QM, while QFT treats them as excitations in a field.
Scientists have developed a framework called quantum field theory, which combines elements of both QFT and QM. This theory allows for the behavior of individual particles to be described by QM, while also taking into account the interactions between particles described by QFT.
Yes, there have been numerous experiments that have confirmed the predictions of QFT, such as the existence of virtual particles and the behavior of particles in the presence of a vacuum. These experiments provide evidence that QFT and QM are compatible theories.
It is currently unknown if QFT and QM can be fully merged into one theory. Some physicists believe that a more fundamental theory, such as string theory, may be able to unify these two theories. However, it is also possible that QFT and QM will always remain separate but complementary theories in our understanding of the subatomic world.