Are supernovae induced by the transformation of M89 nuclei at the stellar surface to ordinary nuclei?

Supernovae as explosions of M₈₉ magnetic bubbles?

Could the explosions of the M₈₉ magnetic bubbles proposed to rise to the planets induce supernovae? The following vision suggests itself.

1. The flux tubes as M₈₉ super-nuclei split to ordinary M₁₀₇ nuclei and produce ordinary nuclear matter and liberate energy. This transition would give an additional contribution to the nuclear matter outside stars compensating for the missing contribution due to the missing ordinary nuclear matter inside stars.
2. The decay of giant M₈₉ nuclei defined by the monopole flux tubes would also create nuclei heavier than Fe, which are not produced in the stellar cores.
3. The pressure pulse created in this way leads to the formation of supernovae and blackhole-like objects? Various giant stars would be the outcome of these kinds of explosions of the M₈₉ surface layer?

One can check whether this hypothesis might make sense in the case of supernovae. I attach here a piece of text from the Wikipedia article about supernovae (see this) almost as such.

1. A supernova occurs during the last evolutionary stages of a massive star, or when a white dwarf is triggered into runaway nuclear fusion. The original object, progenitor, either collapses to a neutron star or black hole, or is completely destroyed to form a diffuse nebula. The peak optical luminosity of a supernova can be comparable to that of an entire galaxy before fading over several weeks or months.
2. Theoretical studies indicate that most supernovae are triggered by one of two basic mechanisms: the sudden re-ignition of nuclear fusion in a white dwarf, or the sudden gravitational collapse of a massive star’s core.
3. In the re-ignition of a white dwarf, the object’s temperature is raised enough to trigger runaway nuclear fusion, completely disrupting the star. Possible causes are an accumulation of material from a binary companion through accretion, or by a stellar merger.
4. In the case of a massive star’s sudden implosion, the core of a massive star will undergo sudden collapse once it is unable to produce sufficient energy from fusion to counteract the star’s own gravity, which must happen once the star begins fusing iron, but may happen during an earlier stage of metal fusion.
5. Supernovae can expel several solar masses of material at speeds up to several percent of the speed of light. This drives an expanding shock wave into the surrounding interstellar medium, sweeping up an expanding shell of gas and dust observed as a supernova remnant. Supernovae are a major source of elements in the interstellar medium from oxygen to rubidium. The expanding shock waves of supernovae can trigger the formation of new stars. Supernovae are a major source of cosmic rays. They might also produce gravitational waves.

These facts suggest that both in the case of white dwarfs and massive stars, the transformation of M₈₉ nuclei to ordinary nuclei triggers the supernova by creating a powerful pressure pulse towards the core of the star.

In the case of a supernova, the mass thrown out is measured using solar mass M_Sun as a unit. For the explosions producing planets, the mass M_E of the Earth is the natural mass unit. Can one understand this?

1. In the case of the Sun The magnetic bubble consists of M₈₉ monopole flux tubes forming a mass of about .005M_Sun. The baryons produced in the transition make mass of about 3ME at most and would compensate for the missing nuclear mass inside the star. A good guess is that the model for the solar M₈₉ bubble generalizes as such so that the fraction of M₈₉ mass scales like (R_star/R_Sun)².
2. For blue giants (see this ), the masses are in the range 10 -300 M_Sun and the radii vary in the range 10 -100 R_E as the table of the Wikipedia article shows. The amount of ordinary baryons produced would be in the range 10²-10⁴M_E at most and considerably smaller than M_Sun∼ 10⁶M_E.
3. In accordance with the expectations, the explosion should also throw out a considerable amount of ordinary nuclear matter. The huge inward directed pressure pulse produced by the transformation of the M₈₉ layer to M₁₀₇ nuclear matter would produce as a reaction a strong inward pulse and this in turn would induce an outward pulse throwing the ordinary nuclear matter out.
4. In the case of white dwarf the inward directed pressure pulse could heat the core and re-ignite a runaway nuclear fusion inducing a total disruption of the white dwarf. In the case of a massive star this could induce a gravitational collapse of the core leading to a blackhole-like object or a neutron star.

To sum up, the TGD based model would solve the problem due to the missing nuclear mass and provide a missing link to the model of supernova. The decay of the giant M₈₉ nuclei to ordinary nuclei would also explain the origin of the nuclei heavier than Fe.

See the article Some solar mysteries or the chapter with the same title.