The standard theoretical model is to assume that there are three different neutrinos with different rest masses in the range 0.05 eV ... 0.5 eV: ν₁, ν₂, ν₃.
Let us have a reaction which creates an electron neutrino νe. The neutrino can be any of mass states ν₁, ν₂, ν₃. We do not know which it is. Various rest masses have various probability amplitudes.
Let α = e. The probability of observing the neutrino as the flavor β at the distance L from its creation is:
where mj are the various neutrino rest masses, and Uαj are constant components from the Pontecorvo et al. 3 × 3 matrix.
The formula on the right sums the waves of different particles: neutrinos with different rest masses m₁, m₂, m₃? That is strange. Is that allowed in quantum mechanics?
In quantum electrodynamics, the electron Dirac field is classical, and can describe an electron or a positron. There we have another case in which we sum waves of different particles: the electron and the positron.
Suppose that a neutrino with a rest mass m flies in vacuum. Obviously, the rest mass of the neutrino cannot change. There cannot be an oscillation of neutrinos if we look at their rest mass.
Anca Tureanu (2025) says that we cannot use the interference of the wave functions of the neutrino wave functions when the neutrinos have different masses
Professor Anca Tureanu from the University of Helsinki says that, in quantum field theory, one is not allowed to calculate interference of wave functions of neutrinos of different rest masses.
A principle in quantum field theory, and in quantum mechanics, is that we can only calculate an interference of two waves if we cannot know which of the two wave histories happened. In the double-slit experiment, we cannot know if the photon passed the left or the right slit. We are allowed to calculate the interference pattern of the two different paths of the photon. But if we place a detector which can determine the path of the photon through the slits, the interference pattern disappears.
In the Nuclear Physics, Section B 1018 (2025) paper, Tureanu writes:
She claims that the end state of a reaction in quantum field theory is a mixed state. A mixed state has classical probabilities. There is no interference of classical probabilities.
But this is a strange claim. In quantum mechanics a "pure" state, that is, a superposition state, stays pure until it is measured. When we measure the outgoing particles, we obtain classical probabilities. The state is no longer pure. The state "decoheres".
Note that the pure state includes ALL outgoing particles. We cannot speak separately of the neutrino.
If we know the location of the reaction well, we do not know the mass state of the created neutrino
Suppose that we prepare the incoming particles in such a way that their momentum (and energy) are known extremely precisely. We measure the energies and the momenta of outgoing particles, except of the neutrino. That way we will know the energy and momentum of the created neutrino, and can determine its rest mass m.
The uncertainty principle says that we then cannot know the location of the reaction precisely:
Δp Δx ≥ ħ / 2.
The flavor probability formula has the parameter L which tells the distance to the reaction.
The energy-momentum relation is
E² = p² + m².
Let E and |p| be roughly 1, and m ≈ 10⁻⁶. To determine a rough value of m from the energy-momentum relation, we have to know p to the precision better than Δp = 1/2 * 10⁻¹². We use natural units, so that ħ = 1. Then
Δx > 10¹².
We see that the formula
exp( -i mj² L / (2 E) )
in the flavor probability equation above then has a relatively large uncertainty because of L:
(10⁻⁶)² * 10¹² / 2 = 0.5.
That is, we know the rest mass of the neutrino, but do not know the neutrino oscillation phase too well. The uncertainty, actually, is quite a lot larger than 0.5 because we must measure momenta of several particles. Also, we chose Δp too optimistically above. A better choice might be 1/3 of the value we chose. Then the uncertainty 0.5 easily becomes 3 or more.
That is, we cannot know the phase of the neutrino oscillation. The flavor probability formula in this case gives the average over a whole cycle of the oscillation. The average is a constant and does not depend on the value of L. This is reasonable.
If we know L relatively precisely, then we cannot know the rest mass state of the neutrino. It makes sense to calculate the sum (interference) of different rest mass waves.
What is the created neutrino? Which state does it have?
If we know the location of the reaction relatively well, then we cannot know the rest mass of the created neutrino.
The created neutrino can then be seen as a "malformed" classical neutrino field wave, which does not have a definite rest mass until we measure the rest mass in some way.
There is only one neutrino particle which has 3 different states? In the model above, there is a single neutrino field which has (stable?) states of three different rest masses. Should we say that the neutrino is just one particle, which appears in three stable states?
An analogous question: are the electron and the positron a single particle which has two states?
Can a neutrino decay to a lower rest mass state? Could it emit a photon?
A particle reaction emits waves, not particles?
In bremsstrahlung, an electron can emit photon(s) of various energies and momenta.
Classically, the electron emits an electromagnetic wave of a complicated form, as the electron e passes the nucleus marked with +. For high energies of the photon, the quantum mechanical calculation yields probability amplitudes which differ surprisingly much from the probabilities one could naively assume from the Fourier decomposition of the classical treatment.
A basic principle of quantum mechanics is that you must treat everything as waves until a measurement is made. You cannot assume that a wave "has collapsed" until it is measured. A typical example of this principle is the Bell inequality: if you assume that there are "hidden variables" which determine the state into which a quantum wave will collapse, then you will calculate results which differ from quantum mechanical results.
This basic principle of quantum mechanics suggests that in a reaction, we must treat outgoing particles as waves, until the particle is measured in a detector.
However, we have a problem here. What is the shape of the bremsstrahlung wave? It cannot be the classical shape. From Feynman diagrams, we can calculate the probability amplitudes of various photons with a momentum p. Could it be that we ger the wave in the momentum space simply by superimposing the waves with different p, multiplied by its probability amplitude? The phase of an individual wave we may get from the position and the momentum change of the electron as it passes the nucleus.
It looks like the model of neutrino oscillation in Wikipedia is compatible with quantum mechanics.
Are the electron, the muon, and the tau particle states of the same particle with different rest masses? What about antiparticles?
The Dirac equation governs these particles, as well as their antiparticles.
Do we know anything about interference of electron and positron waves? What about interference of electron and muon waves?
An electron colliding with a nucleus
The bremsstrahlung reaction creates photons. Let us forget photons for a moment, and look at the wave function of the electron colliding with the nucleus.
We may assume that the nucleus is moving at a velocity v, so that, depending on its path, the electron may gain or lose some kinetic energy.
-------------
/ v \
e- -------- <-- ● Z -----------> p'
p --------------------------------------> p''
The Schrödinger equation describes the behavior of the electron e-. The initial momentum of the electron is p.
In the diagram above, we have two alternative paths for the electron. Depending on the path, the electron exits with a momentum p' or p''.
The momentum of the nucleus changes by an amount p - p', or p - p''.
In the Schrödinger equation, the waves for different paths of the electron do interfere, even though the electron in each path has a different kinetic energy and momentum.
The collision can be considered a "reaction". The particle e- exits the reaction. The electron in each path has a different "state".
The collision is actually a "double-slit" experiment, in which the nucleus forms the obstacle between the two "slits".
We conclude that in quantum mechanics, the waves of a particle do interfere, even though the waves correspond to different kinetic states of the particle.
In the case of neutrino oscillations, the neutrino can be in different rest mass states. Could it be that having a different rest mass removes the interference? Is having a different rest mass a "kinetic state"?
A simplified model of an excited hydrogen atom
An excited hydrogen atom has a "rest mass" which is larger than of the atom in the lowest energy state. What do we know about the interference of hydrogen atoms?
People have been able to run the double-slit experiment with large molecules, like the "buckyball". This suggests that we should be able to see interference between a hydrogen atom in the ground state and the same atom in an excited state.
If we have no way of knowing if the atom is excited or not, why would interference disappear? We can measure the rest mass later, and we will know. But the same hold for the electron in the previous section: we can measure the momentum of the electron later – this does not prevent interference from occurring between electrons which have different momenta.
y position of proton
^
|
|
|
|
--------------------------> x position of e-
Let us consider the following simplified model of a hydrogen atom. We have one spatial dimension in the world. The y coordinate tells the position of the proton. The x coordinate is the position of the electron. That is, we model both particles with one particle whose spatial coordinates are (x, y).
The potential:
V = 1 / | x - y |.
If we fix y to some value, the wave function is somewhat like a particle in a box.
The inertia of our one particle is larger in the y direction than to the x direction. The proton is heavier.
In this simple model, there most probably is interference between different momentum states of the proton?
*** WORK IN PROGRESS ***








