Fun scifi hypothesis - the only stars that don't go supernova as a part of collapse into a black hole are ones that are engineered to do so by the locals.
I think it’s all constraint based, with a black hole being an n-scale closure. So in this model, a star collapsing with no supernova is where there is simply little to no excess after the closure occurs.
I’ve a version of this that uses only local adjacency rules by which a dynamic lattice emerges. Hit me up if you want to know more, but it connects these: Fano Plane, S(5,8,24), and Golay Code, and the leech lattice
You cannot enter a black hole, they have no interior. They are pure curved space, literally an inverse of normal space.
Pi is actually not invariant in the discrete world! The continuum illusion is only intermittently tangent to the underlying discrete reality. The tick tock of the universe is a xor, local and global constraints resolve perfectly because everything is connected via perfect inviolable discrete parity on a discrete leech-like lattice, whereby shells embedded in the lattice can and must simplify to preserve parity. No ontic fields, they are but quotients on the current state at some scale. Particles are dynamic closure witnesses which can group and “propagate”. I have a simulator, but the calculation time grows so very quickly.
Only stars significantly bigger than the Sun go through a supernova explosion, and such big stars are a small fraction from the total number of stars.
Moreover, the rate of seeing supernovas depends both on the number of stars that can become supernovas and on the lifetime duration for such stars.
Therefore, even in a hypothetic world where all the stars could become supernovas one might see a very small number of supernovas if the lifetime of stars were great enough.
Thus the frequency of seeing supernovas is not sufficient for any conclusion, without taking in consideration the proportion of stars susceptible to become supernovas and their average lifetime.
pavel_lishin|15 days ago
CompromisedTool|14 days ago
I’ve a version of this that uses only local adjacency rules by which a dynamic lattice emerges. Hit me up if you want to know more, but it connects these: Fano Plane, S(5,8,24), and Golay Code, and the leech lattice
You cannot enter a black hole, they have no interior. They are pure curved space, literally an inverse of normal space.
Pi is actually not invariant in the discrete world! The continuum illusion is only intermittently tangent to the underlying discrete reality. The tick tock of the universe is a xor, local and global constraints resolve perfectly because everything is connected via perfect inviolable discrete parity on a discrete leech-like lattice, whereby shells embedded in the lattice can and must simplify to preserve parity. No ontic fields, they are but quotients on the current state at some scale. Particles are dynamic closure witnesses which can group and “propagate”. I have a simulator, but the calculation time grows so very quickly.
fooker|16 days ago
We'd be seeing a lot more supernovas in the night sky if all/most stars had to go through one.
adrian_b|16 days ago
Moreover, the rate of seeing supernovas depends both on the number of stars that can become supernovas and on the lifetime duration for such stars.
Therefore, even in a hypothetic world where all the stars could become supernovas one might see a very small number of supernovas if the lifetime of stars were great enough.
Thus the frequency of seeing supernovas is not sufficient for any conclusion, without taking in consideration the proportion of stars susceptible to become supernovas and their average lifetime.