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As stars evolve so do their magnetospheres. This is a direct result of core formation (of iron/nickel composite) to sustain constant convection, and the formation of a very strong global magnetic field which then dominates the chaotic surface magnetic fields. This understanding of course does not exist in establishment astrophysics. The Sun isn't going to become some surrealistic red giant, it will shrink and become an orange dwarf, and then a red dwarf and form a very strong global magnetic field. https://www.youtube.com/watch?v=AB2nwA4TWm8
Nobody but you cares how many times this thread has been viewed. >10000 views doesn't mean you have any converts, or are even getting "the word" out. You're the only one who has posted to this thread since March. Who knows how many of these views are from you, or someone looking for a laugh.I don't see any real dialogue on this thread for almost a year now--it seems as though everyone else has moved on...
My theory, is our sun is a second generation star. The first generation of the sun formed earlier in the universe and went through an expansion phase that deposited the materials from which the planets would form. The heaviest materials stayed closer to the remnants of the sun, to form the inner rocky planets and the light materials went out further to form the gas planets. The sun then reforms from the balance, to start again. The reason for the expansion/explosion of the first generation sun was connected the heavier atoms it had been forming from fusion. Heavy atoms will float above the fusion core instead of sinking. The reason larger atoms will float and smaller atoms will sink is because larger atoms will gain 1S electrons and will therefore lower their effective density. The smallest atoms like hydrogen remain at nucleus density, instead of electron cloud density. As an analogy, iron or steel will sink in water because it has a higher density. However, if we fabricate the steel into the hull of a ship, iron will now float on water. The hull adds volume so the overall density of the iron become less than that of the water. The hull of the heavier atoms will be the electron clouds which will increase their effective volume. What his brings to the table is the fusion core accumulates a heavier atomic shell that floats above the core, like ships on water. Smaller but denser atoms have to diffuse through this driven by the pressure density affect. If the fusion core of our sun, for example, begins to burn hotter, this will ionize the shell, making it become denser, thereby sealing the shell tighter, lowering the fuel diffusion rate. As the core cools, the shell will gain more electrons and will expand and float higher, allowing easier diffusion into the core. This is reflected in sun spots and solar flares, respectively, with shell preventing run-away fusion from the core outward. A surge of fuel into the core, followed by a flare up burn, will create a local expansion hammer effect, against the contracting shell, from which even higher elements can appear even in first generation stars. Hydrogen and helium become imbedded into the larger more ionized atoms of the hot collapsing shell. As more and more material collects in the shell, diffusion of lighter fuel atoms, will become increasingly restricted and rate limiting. This cools the core and will cause the shell to expand more until diffusion is restored. The result, over time can be a backdraft, as the restricted fuel surges into the smoldering core; boom! The star blasts off a part of its shell. Depending on the blast magnitude, the shell material can remain close enough for many planets to form from the debris.