Good question!

PET Voids vs. Standard Model (SM) Particles: Our 1D “voids” are simplified analogues – think of them as toy models for what fundamental particles might be at a deeper level. SM particles (like electrons) are much more complex, described by quantum fields, and have properties like charge and spin that our 1D voids don’t explicitly have yet.

“Passing Through” – Wave Nature is Key:

If you think of particles as tiny hard balls, them passing through each other sounds odd. But in quantum mechanics, all particles also behave like waves. And waves (like ripples on a pond or light beams) do pass through each other all the time. This is a better analogy for what we’re seeing.

The structures in our PET model are behaving like solitons, which are special, very stable wave packets that are known for their ability to pass through each other and maintain their identity.

How Do SM Particles “Pass Through”?

Weakly Interacting Particles: Something like a neutrino interacts so weakly it can pass through the entire Earth. This is “passing through” due to a tiny chance of hitting anything.

Photons (Light): Light beams pass through each other without issue.

Strongly Interacting Particles (e.g., Protons, Electrons): When these “collide,” they typically scatter due to the fundamental forces between them (electromagnetism, strong force). They don’t usually pass through each other unchanged like our PET solitons do in these 1D simulations. Their interactions are more about exchanging force particles and changing trajectories, or even creating new particles.

Is This PET Behavior “Observed” or “Testable Soon”?

Directly, No: We can’t find these specific 1D ether voids in a lab experiment. They are part of our theoretical model.

Indirectly/Conceptually: The idea of particles being soliton-like excitations of an underlying field or medium is explored in various areas of theoretical physics (e.g., some models for magnetic monopoles, or structures in Bose-Einstein condensates). So, the concept of soliton-like entities is well-established.

Testing PET: For PET itself to be testable, we need to develop it much further (especially into 3D) to see if it can make predictions that match real-world observations or, even better, predict something new that experimenters could look for. That’s a very long-term goal.

In essence: The soliton-like “pass-through” in our 1D PET model is exciting because it shows our simple ether can produce structures with very robust, non-trivial, particle-like interaction properties (maintaining identity after collision). This is a key behavior we’d want our particle analogues to have. While it’s not a direct match for how all Standard Model particles interact (especially strongly interacting ones), the wave-like nature and the concept of stable, extended structures are important themes in fundamental physics. Our current work is about seeing if these themes can emerge naturally from a single ether.

Hope this helps clarify!"

This response aims to be accurate, manage expectations, but also convey why the soliton-like behavior is a significant and positive finding within the context of your theoretical exploration. Good luck with the Reddit discussion!