I'd suggest considering neutrinos to be two influencing effects that cause one of the slightest mathematical and measurable effects.
When the energy flows over a larger course that longer loop is influenced more significantly by nuclei nearby. Those passing nuclei creating loops in the energy flow momentarily drawn by the other nuclei yet still within the strong force range of retention. Depending on the thermal dynamics of nearby nuclei, these energy loops may be considered as weak forces or potentially neutrino launch pads.
src: Quarks =>
To expand on the above a loop can have an effect on a system governed by the left or right hand rule. We might also want to focus attention on accuracy of bosonic pathing in and around fermions should probably be governed by a mean 3D surface to properly compute the loop count. Also, how long the loops last and when they reverse with respect to cycling bosonic pathing throughout the fermion is something fresh to visualize.
A review would be the change of everything else outside of a system causes wiggle. Warpage within the system that will resonate back to return to center and is one of the smallest effects of our measurable range. So that makes me wonder of the perpendicular geometry of extruding the systems warp to the rest of the universe while the wiggle returns to zero. The reason I like to think of that flux-flex-flux is it seems like maybe that's the traversing channel of neutrino flip via different states. Although, I think the flips could also be the switch between axis of measure.
src: Dark Radiance =>
Dark Radiance is one way to consider interactions between nuclei, perhaps similar to the influences of nearby nuclei described in the Quarks page or a balance, inter-supportive.
When a gravitational wave might change the state of a neutrino launch loop causing a sudden shift of direction.
That might be considered a mathematically significant yet observably inappreciable state change. Could the subsequent redraws of the quarks repeat the same effect over a time or was that a launch that doesn't constantly influence change? Perhaps if you're considering the proton to be constantly redrawn by photonic pathing then the next would include a inverse, or every other depending on what mathematically would happen in such a computed model.
To consider the changing types of three different neutrinos that seem to suddenly flip between the three over seemly long spans of time & distance. It seems easier to consider neutrinos flipping direction in the X, Y, and Z plane like something free spinning can tend to do in free fall or gravitational equilibrium. To guess far out, maybe nucleic rotation while launching a neutrino creates a pattern that can find a everchanging inertial balance of three orthogonal axis causing the internal mass redistribution in simile with the local galaxy's shape. That last sentence is a big bite, so an alternative simile would be a yarn ball that has three distinct distributions of yarn when the spin of the ball unwinds and ravels. This video shows a flip of two states in this handle rapidly unthreaded and left to free spin ytDancing T-handle In Free Fall =>, imagine a third state, temporal balance. I think this can help us determine a neutrino particle would bosonic in that there is enough freedom of change to flip between three directional states possibly changes rotational speed in the process like a tighter or looser knot would influence torque velocity.
It's interesting that neutrinos might not show any electrical flow. Is that due to a lack of instrument sensitivity or a bounce between gravity & magnetism? A Cherenkov of blue glow traces after the neutrino. Energy packet sizes, perhaps the electronic effect is nullified in the conical shape, like a circular permiation of electronic vectors, the sweaping spiral of interaction. If there's a signal spike from a super massive black hole that's 400 million LY away then is that the decompression process of random tendrils of energy after large masses are absorbed and the wave dynamics relax. Is that a mass effect of the propegation of the unraveling of energy like a compression force that doesn't need to exert an electronic effect on the system. If the release of bonic plasmas could be a kelvin cooler, then doesn't that add to the compression of localized molecular forces? If for a moment a massive black hole goes from a lens shape to a sphere, maybe due to rotation and spin that points towards earth occasionally then there might be a lime squeezing effect on spacetime local that temporarily starts to draw out bosonic energy then tendrils out when the surface returns within a consistent lattice.