kimbyd said:I don't think that makes sense as an explanation, because in that instance this decay is also possible:
[tex]\mu \rightarrow e + \gamma[/tex]
Since the photon has zero mass, it is kinematically favored over the neutrino decays.
The Wikipedia article points out that this decay is possible through neutrino oscillation of a virtual neutrino, but this is highly unlikely, probably due to the short amount of time involved for the decay interaction.
For the most part, the curvature of space-time is low enough that the fact that it isn't flat space-time is irrelevant. Just do the quantum examination for the case where space-time is flat and you'll get close to correct.Carlos L. Janer said:What makes no sense to me is to consider the propagation of the quantum superposition of three particles in a classical curved space-time. Unfortunately, I am not aware that we have such a theory. Using QFT formalism in a curved space-time is contradictory (there's no Poincaré invariance). I don't know how it possibly work.
It is not really an amount of time involved in internal lines in a Feynman diagram.kimbyd said:The Wikipedia article points out that this decay is possible through neutrino oscillation of a virtual neutrino, but this is highly unlikely, probably due to the short amount of time involved for the decay interaction.
kimbyd said:For the most part, the curvature of space-time is low enough that the fact that it isn't flat space-time is irrelevant. Just do the quantum examination for the case where space-time is flat and you'll get close to correct.
This breaks down if you're close to a black hole, but works fine in most other cases.
kimbyd said:For the most part, the curvature of space-time is low enough that the fact that it isn't flat space-time is irrelevant. Just do the quantum examination for the case where space-time is flat and you'll get close to correct.
That doesn't make sense to me. It could potentially explain why the ##e^- + e^+ + e^-## decay is disfavored, because the neutrinos are so much lighter than the electrons the decay to neutrinos will be far more common. That doesn't explain why the ##e^- + \gamma## decay is disfavored, as the photon is even less massive.mfb said:It is not really an amount of time involved in internal lines in a Feynman diagram.
You say the same thing in different words. All the flavor violating decays are extremely unlikely because the neutrinos are so light.
Unfortunately I'm not aware of any references offhand. You'd likely be able to search for them about as well as I can.Carlos L. Janer said:Could you give me some references where I could check under what assumptions that aproximation is valid?
kimbyd said:Unfortunately I'm not aware of any references offhand. You'd likely be able to search for them about as well as I can.
But the picture is pretty simple: quantum superpositions only really matter in two general cases:
1. There's some kind of discontinuity, such as an event horizon. What happens if one part of the superposition crosses, but the other does not? Thus there are likely issues near black holes with the flat-space approximation.
2. The quantum system produces significant space-time curvature. In this case, because we can't properly describe how a superposition of states impacts space-time curvature, we can't say how such a system gravitates. This isn't really relevant for neutrinos because their density isn't high enough for any significant gravitational effect. It would have been high enough in the early universe, but back then the neutrinos were thermalized enough that they could be treated classically.
Draw the Feynman diagram for ##\mu \to e \gamma##. It has a neutrino oscillating to a different neutrino type.kimbyd said:That doesn't make sense to me. It could potentially explain why the ##e^- + e^+ + e^-## decay is disfavored, because the neutrinos are so much lighter than the electrons the decay to neutrinos will be far more common. That doesn't explain why the ##e^- + \gamma## decay is disfavored, as the photon is even less massive.
Where do you get the statement that it's the small neutrino mass that is important in these decay rates?
No, I don't think we can rule out a BSM decay. I thought I had been explicit that such a decay, if it exists, would be beyond the standard model, because it would require a lack of conservation of flavor. My understanding is that the ways in which flavor is not conserved in the standard model just don't apply to these sorts of interactions.Carlos L. Janer said:However, you're ruling out yourself the possibility for the more massive neutrinos to quickly decay (by an interaction that is beyond the Standard Model) to the lightest one and I thought it was the idea that you were trying to explore with mfb and the reason you were having this conversation with Vanadium50 and mfb.
That's what I'm trying to say: the low neutrino mass isn't the dominant factor in suppressing such interactions.mfb said:Draw the Feynman diagram for ##\mu \to e \gamma##. It has a neutrino oscillating to a different neutrino type. The photon mass doesn't matter. The process is rare due to the flavor violation.
But... it is!kimbyd said:That's what I'm trying to say: the low neutrino mass isn't the dominant factor in suppressing such interactions.
kimbyd said:There's some kind of discontinuity, such as an event horizon. What happens if one part of the superposition crosses, but the other does not?
Why is that?mfb said:But... it is!
Flavor violation is rare because the neutrinos are light.
Carlos L. Janer said:What makes no sense to me is to consider the propagation of the quantum superposition of three particles in a classical curved space-time. Unfortunately, I am not aware that we have such a theory. Using QFT formalism in a curved space-time is contradictory (there's no Poincaré invariance). I don't know how it could possibly work.
I'm not sure what you're asking here. Could you please clarify?Carlos L. Janer said:What is (or, better, could be) the renormalization (semi) group flow of the neutrino mass matrix? What particles could be involved? I suppose they're not the only parameters that do (could) flow. What are (could be) the others?
I don't think there's any chance of this. Even a very small electric charge would overwhelm the weak force for most interactions, making neutrinos visible in a number of experiments where they are currently invisible. Here's one paper I found that went into these limits back in 1999:Carlos L. Janer said:Is it conceivable that neutrinos could carry a tiny electrical charge?
Carlos L. Janer said:Using QFT formalism in a curved space-time is contradictory (there's no Poincaré invariance). I don't know how it could possibly work.
kimbyd said:I'm not sure what you're asking here. Could you please clarify?
PeterDonis said:You should be very careful about extrapolating "I don't know" into "it's contradictory". QFT in curved spacetime is perfectly possible. See, for example, Wald's 1993 monograph "Quantum Field Theory in Curved Spacetime and Black Hole Thermodynamics". The basic idea is to first reformulate QFT in flat spacetime in a way that does not rely on global Poincare invariance, and then extend the reformulated version to curved spacetime. But it's not a simple exercise.
Carlos L. Janer said:I've been told (by some other staff members) that this only works when you study Hawking's radiation and becomes useless when you try apply these ideas to the universe.
mfb said:We cannot rule out neutrino/photon interactions, and at loop-level we have them even in the SM, but they have to be extremely weak. And that is elastic scattering - I still don't see how you would get a decay.
Carlos L. Janer said:the idea that the parameter values involved in elementary particle interactions (mass, "charge" or interaction strength and field normalization constant) depended on the interaction energy scale was deeply engraved in my mind.
Carlos L. Janer said:the renormalization of the unitary matrix that relates neutrino flavor eigenstates to neutrino mass eigenstates