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On the opposite bank of the Yellowstone River, I observed 4 or possibly 5 otteron particles had merged into a quantum incompressible fluid which would occasionally degrade into a multi-headed classic fluid and then reform.

I believe the unusual, extreme fluid had been created by subtle interactions of a persistent pressure field generated by touron particles on my side of the river which were taking extensive telephoto shots of the system and a strong attraction field from the river.

This is supported by the phase transition to a classical fluid occurring simultaneously with a otteron-looking-at-tourons behavior - indicating that there was a substantial interaction with touron fields and that it was linked to the quantum/classical oscillation.

This reminds me of my observation of a well-compressed, high temperature classical elkon gas system which I speculate had been under pressure from predatoron fields outside of my region of observation - grizons or wolfons being the likely candidates. A small number of neighboring tourons may have actually been acting in second order as a limited attractive force in this case too, since predatorons are repelled more strongly by touron fields than elkons are.

Perhaps, a combination of attraction and repulsion fields are necessary for this sort of dynamics to establish itself. Both sorts of particles mentioned above are strongly self-attracting as well, which probably is an essential pre-condition for the establishment of these sorts of fluids.

The non-classical nature (and also the incompressibility) of the multi-otteron field was surprising since this researcher expected otteron particles to remain distinguishable under the circumstances. Otterons tend to easily achieve high excitation energies which would cause the group to readily transition to a gas. That this didn't happen for several minutes of observation (the transitions to classical dynamics were brief and resulted in no expansion of the volume of the system) was very interesting and hints at unknown physics. I dimly recall that if one cools the system to liquid nitrogen temperatures, the otteron particles become sessile and classical - that is, easily distinguishable from one another. This system actually enters a quantum regime as temperature increases, which is an extremely rare phenomena!

As a side note, the elkon gas cloud exhibited the genderon symmetry breaking typical of elkon dynamics with the cloud consisting solely of doeons. I didn't have tools available to distinguish genderon state of the otteron particles, but the establishment of quantum dynamics may mean that the otterons didn't have such, or that the factor being quantitized was independent of genderon field dynamics somehow.