The Finger of God at Work
My Theory on Other Big Bangs
Are there other universes? Yes, but other universes are not exactly like our universe, and I will explain why.
When stars reach the end of their lives, what happens next depends a lot on their mass. Some stars collapse into black holes while others do not. Here is my theory on what happens:
Different sized stars collapse into black holes, creating different types of singularities. Not all singularities are the same because of the varying sizes of the collapsing stars.
The singularity that exploded and created our universe is significantly different from other singularities that explode and create other universes. This is due to the varying sizes of the collapsing stars that form these singularities.
The elements in these singularities are different because of the size of the star that created them. Different sized stars contain different elements before they collapse and create a singularity. This is why singularities, and thus the universes they create, are so unique.
So, now you can see how important the human conscience is. There is no other like it anywhere.
The singularities will never stop exploding and creating new universes. However, all universes will eventually come to an end. In these universes, both good and bad are created. The good that is created will go to heaven, while the bad will go to hell.
The Sun is a pretty average-sized star, but when you compare it to other stars out there, you find some that are way bigger and some that are smaller. The size of stars can vary a lot.
Red Dwarfs: These are smaller than the Sun. They’re the most common type of star in the Milky Way, and they can be as small as 0.08 times the Sun’s mass.
Main Sequence Stars (like the Sun): These are medium-sized stars. The Sun’s radius is about 696,340 kilometers.
Giant Stars: These stars are much larger than the Sun. For example, Betelgeuse, a red giant in the constellation Orion, has a radius about 1,000 times that of the Sun. If Betelgeuse were placed at the center of our solar system, it would extend beyond the orbit of Mars!
Supergiant’s: These stars are even bigger. For example, VY Canis Majoris is one of the largest known stars. It’s a red hypergiant with a radius around 1,500 to 2,100 times that of the Sun.
Hypergiants: These are the absolute largest stars. They’re rare and incredibly massive. One of the largest is UY Scuti, with a radius roughly 1,700 times that of the Sun.
So, to sum it up, stars can be much bigger than the Sun, with the largest known stars having radii over 1,500 times that of our Sun. But remember, there are also many stars that are smaller than the Sun!
When stars reach the end of their lives, what happens next depends a lot on their mass. Here’s a breakdown of which stars can turn into black holes:
Low-Mass Stars (up to about 8 times the mass of the Sun):
These stars end their lives by shedding their outer layers, creating a planetary nebula, and leaving behind a white dwarf. White dwarfs are very dense but don’t become black holes.
Intermediate-Mass Stars (8 to 20 times the mass of the Sun):
These stars can explode in a supernova, leaving behind a neutron star. If the remaining core is between 1.4 and about 3 times the mass of the Sun, it will become a neutron star, which is incredibly dense but not a black hole.
High-Mass Stars (more than 20 times the mass of the Sun):
These stars also end in a supernova, but if the core left behind is more than about 3 times the mass of the Sun, the gravity is so strong that nothing can stop the collapse, and it turns into a black hole.
So, the stars that become black holes are those that start off with more than about 20 times the mass of the Sun. These massive stars have enough gravity to compress the core left over from the supernova explosion into a black hole.
Atom
An atom is the smallest unit of ordinary matter that forms a chemical element. Each atom consists of three main parts: protons, neutrons, and electrons.
Nucleus: This is the center of the atom and contains protons and neutrons.
Protons are positively charged particles.
Neutrons have no charge (they are neutral).
Electrons: These are negatively charged particles that orbit the nucleus in various energy levels or shells.
Here’s a bit more detail about each part:
Protons: The number of protons in an atom’s nucleus defines the element. For example, hydrogen has 1 proton, carbon has 6.
Neutrons: These add mass to the atom but don’t affect its charge. The number of neutrons can vary within atoms of the same element, leading to different isotopes.
Electrons: These orbit the nucleus in regions called electron shells or energy levels. Electrons determine the atom’s chemical properties and how it bonds with other atoms.
Atoms are incredibly small. For context, a single strand of human hair is about 1 million atoms wide. Despite their size, atoms are the building blocks of everything around us.
The singularity I’m talking about is smaller than an atom.
Singularity
A singularity is thought to be a point where all the matter and energy of the universe were concentrated in an extremely dense and hot state. It wasn’t made up of particles like protons; it was something much more extreme. The laws of physics as we know them break down at that point, so it’s not like any particle or object we can imagine.
Here’s the image comparing UY Scuti, the largest known star, to the Sun. As you can see, UY Scuti is depicted as a gigantic red supergiant star, making the Sun appear tiny in comparison. The background features the vastness of space with scattered stars, emphasizing the immense size difference between the two stars.
When two black holes collide and merge into one black hole, do their singularities also collide and form a single singularity? This is another fascinating question that leads to a new theory.
