Hi, renormalizing is a necessity, but the problem is the interval L. For an electron traveling freely, that interval is pretty much infinity? Even worse, if that electron is oscillating in an area which is unknown for its dimensions, then how can one treat L? As a parameter?Iliody said:I don't think so... You can try using a different basis for the wavefunctions, but the zero point energy will end being equivalent to the standard formula... You can renormalize it adding a constant that has the same kind of divergence, and it won't mess up anything more on your theory, so... It's a good thing to do.
It's ok my answer?
Not sure what you mean. Do you mean the limits of E_0 as L goes for from 0 to infinity?BvU said:Is taking the limit(s) of the non-alternative form such a bad idea ?
SeM said:...the problem is the interval L. For an electron traveling freely, that interval is pretty much infinity? ... oscillating in an area which is unknown for its dimensions, then how can one treat L?
Thanks , I think setting the eigenenergy to zero gives a somewhat unrealistic initial condition. However, I would like to thank you for your comments in any case!Iliody said:You regularize first, restricting the base of first-quantized wavefunctions with which you make the base of second-quantized wavefunctions, being them normalized, then you diagonalize your Hamiltonian (plus a renormalizing constant that depends on the regularization), and then you look for the lower eigenval. That eigenval is the zero energy, and (my opinion) you can set it to zero by renormalization (when there are no symmetries in tour theory forbiding it).
Good look!
Pd: I am not sure about how common is that this is opinion is shared in the physics comunity, so it's maybe wrong that I put this answer here.
This is a particle in a Quantum Hall. cosmological constants- would they affect it? Which cosmological constant do you mean?Iliody said:If de don't include gravity in our discussion, it's ok to ser it to any value, if you include gravity, you need to set it to the cosmological constant. I never did perturbative QG calculations (they can be done to one loop if we don't put matter loop corrections in gravity-gravity scattering), so I don't know how many quantities depende on the cosmo-constant.
Sorry, I thinked that you were talking about other kind of system. I don't remember anything about Quantum Hall... And I remembered now that my affirmations were limited to QFT correlation functions without boundaries (infinite volume limit). There are observables like presure that depend on the zero point energy in a nontrivial way (even in that case, the thing that I said about zero energy renormalization-regularization).SeM said:This is a particle in a Quantum Hall.
Hi, QFT may have indeed some important common themes with the Quantum Hall. However, is there a "starting" point, or some initial condition one uses in QFT for wavefunction study?Iliody said:Sorry, I thinked that you were talking about other kind of system. I don't remember anything about Quantum Hall... And I remembered now that my affirmations were limited to QFT correlation functions without boundaries (infinite volume limit). There are observables like presure that depend on the zero point energy in a nontrivial way (even in that case, the thing that I said about zero energy renormalization-regularization).
SeM said:Is there a "starting" point, or some initial condition one uses in QFT for wavefunction study?
how does this vacuum state look like in terms of function/value/expression?Iliody said:Mmm... It's usually taken a vacuum state at the infinite past & at the infinite future, and you change that state inserting operators add particle exitations (first-quantized non-interacting wavefunctions) of the different fields. That has a lot of troubles, in some sense.
It's the state annihilated by all field anihillation operators, that are Fourier modes of the field operators.SeM said:how does this vacuum state look like in terms of function/value/expression?
The zero point energy is the lowest possible energy that a quantum mechanical physical system may have. It is the energy that remains in a system even at absolute zero temperature when all other forms of energy are removed.
Currently, there is no alternative form of the zero point energy that has been scientifically proven. However, there are theories and speculations about the existence of dark energy which could potentially be an alternative form of the zero point energy.
The zero point energy is believed to play a significant role in the expansion of the universe. It is thought to contribute to the overall mass and energy of the universe and can influence the structure and behavior of matter on a microscopic level.
Currently, there is no known way to harness the zero point energy for practical use. The energy is incredibly small and difficult to access, making it impractical for use in technology. However, research and studies are ongoing to explore the potential applications of zero point energy.
The existence of the zero point energy is a well-established concept in quantum mechanics and has been supported by numerous experiments and observations. However, there are still ongoing debates and research to fully understand and explain the role and properties of this energy in the universe.