Fusion happens in stars, black holes, and planets.



As neutronium in fusion state was dispersed by the Big Bang, all varieties of gravitation exhibiting entities formed. Naturally. the largest chunk in the Milky Way galaxy resides at the center as a supermassive black hole around which everything in our galaxy revolves.

What forms at the point of a given Big Bang dispersed neutron fusion cluster depends on factors including the mass of the neutronium and the properties of the matter that happens to be in its vicinity. Celestial bodies of varying types form, all in accord with the mass of their respective fusioning neutronium centers. Such entities include black holes and stars. There are more than 60 identified types of stars. Our sun is a G-type main sequence star.

It is simple enough to understand how the neutronium mass at the center leads to specific formations. Our Sun is of such mass that it efficiently draws and engages surrounding material, primarily hydrogen, in an ongoing, long term (from our perspective) fusion process. The Sun has a mass of 1 M.

Bodies with a greater mass, contingent upon the size of the neutronium core that is in fusion, of say 1.25 to 1.4 M, typically form neutron stars. Stars range in size from 450 times smaller than the Sun to 1000 times larger. Large neutronium masses lead to the formation of stellar black holes of masses ranging from 10 to 100 M. It is difficult to gauge exactly what forms in a specified mass range, or the speculate on the influence of the properties of surrounding matter. The important point is to understand that neutronium in fusion is the core process leading to all of these creations.

So how does neutronium in fusion relate to the formation of celestial entities including planets, moons, planetoids, and comets?  The principle process for the formation of a planet begins with a much smaller mass of neutronium in fusion than would lead to the evolution of a star. While the neutronium center of a planet (or planetoid, or moon, or comet) isn’t of sufficient energy to ignite into a star, or to draw so much matter with such force that it collapses into a black hole, it does attract matter. The matter that is attracted into this neutronium induced gravitational center layers itself, according to density, around the neutronium core. Inevitably, an inert layer develops into a crust. The process continues. The planet (or planetoid, or moon, or comet) grows in size, its eventual overall mass predicated, basically, on the size, rather strength, of the neutronium core.