User blog:Fuzzo the fuzzy bee/Shelledverse

The shelledverse is a strange verse.

Border
The soft border is part of the shelledverse’s border. It is soft and fairly easy to break through, however it regrows quickly. It also is pretty thicc. The hard border is a part of the shelledverse’s border. It is hard and not easy to get through, but it takes a while to regrow. Trying to get through it might damage your tools. This border is only partially solid. If you touch it, you get lit on fire. The solid parts are really hot but easy to break through. The fire border sometimes damages the Hard Border. The final border is a really hard to break border that is very bouncy so you get bounced off if you try to get through. It’s so hard to get through that attempts rarely succeed without teleporting through it.
 * -|Soft border=
 * -|Hard border=
 * -|Fire border=
 * -|Final border=

Core
The outer core is hot liquid that is a few octillion celcius. There are some blocks of ice on the outer core that are below absolute zero somehow. The outer core is mysterious because of this, as nobody knows why or how any of this happened. The inner core is a large area of metal that is somehow dangerous to touch due to being sharp even though it isn’t sharp. This is also a mysterious layer because we don’t know how it works, but we do know that you cannot teleport through it. For some reason there are tunnels that go through it, but nobody lives there. The central core is a large dodecahedron with borders made of grass and a hollow interior that has a glowing ball in the center. The orb is super bright and also powers this entire verse. It is not possible to move or destroy the glowing ball. Attempts to do so will have it release a ton of energy that will probably kill you.
 * -|Outer core=
 * -|Inner core=
 * -|Central core=

Squircleverses
The squircleverse is a circular square triangle that has Galaxies in it and it also has a core that powers it. Squircleverses are about 1/5 the size of a Universe. Squircleverses take up 1% of the space in the Shelledverse, so there are quite a lot of them. Megasquircleverses are squircleverses that are 100x as large and have a 1/500 chance to replace a squircleverse. They, instead of having galaxies, have about 30 squircleverses in them. Their cores are more unstable. Megasquircleverses are dangerous because of this. These have a 1/500 chance to replace a Megasquircleverse, meaning it has a 1/250,000 chance to replace a squircleverse. It is 100x as large as a Megasquircleverse and has about 30 Megasquircleverses in them. Unlike Megasquircleverses, Gigasquircleverses have a stable core. The core is more stable than a regular squircleverse’s. Has a 1/125,000,000 chance to replace a squircleverse since it has a 1/500 chance tp replace a Gigasquircleverse. It’s 100x as big as a Gigasquircleverse and has a moderately stable core. It doesn’t have 30 Gigasquircleverses in it, it actually has 50, meaning that half of the space inside the Ultrasquircleverse is taken up by Gigasquircleverses. 1 in 62,500,000,000 chance to replace a Squircleverse since it has a 1/500 chance to replace an ultrasquircleverse blah blah blah. It has an unstable core and this makes the verses inside it in more danger than the ones outside. Omnisquircleberses have 45 Ultrasquircleverses inside it and is 100x the size, as you would’ve guessed by now.
 * -|Squircleverse=
 * -|Megasquircleverse=
 * -|Gigasquircleverse=
 * -|Ultrasquircleverse=
 * -|Omnisquircleverse=

Unique stars
Purple Hypergiants are things that appear when 2 purple giants collide at the perfect speed. They fuse together into this thing. This also can sometimes form instead of a Purple Giant. It’s just a really big version of a purple giant. White giants are stars that are formed when something goes wrong with a supernova and the white dwarf ends up being way too big. These stars are an anomaly. They are like white dwarfs but bigger but still dead. White giants eventually turn into these. These don’t do much except for be surprisingly large. The largest type of failed star. This forms when a star that gets really large fails and becomes a brown dwarf. This makes it rare. It also sometimes is able to get back on track and turn into a red giant or a main sequence star and not fail. Green hypergiants are formed when a green supergiant gets close to a purple hypergiant. The green supergiant sucks up mass from the purple hypergiant and the green supergiant grows larger and becomes a green Hypergiant. These just produce a ton of energy. It can’t do this to other stars because the purple hypergiant is the only one where it can maintain the hypergiant status for some reason. These produce a lot of energy and are formed sometimes instead of a red supergiant if it fails to become a hypergiant but almost gets there, for some reason it shrinks a little bit but stays as a supergiant and then somehow turns green. It sucks up mass from other stars and can turn them into gray dwarfs. Very tiny stars formed when the green supergiant sucks up all mass from other stars. These produce almost no light or energy and are non-hot enough for a human to survive in one for about a minute. They are the smallest star types that aren’t cheating (cheating=neutron stars and black holes) This is what happens when a green hypergiant sucks up energy from a green supergiant. The supergiant gets smaller and becomes a green dwarf. It will constantly attempt to suck up energy to get back to being a Green Supergiant. It produces a lot of energy for it’s size. This is what happens to the Purple Hypergiant when the Green Supergiant uses it to become a Green Hypergiant. The purple giant doesn’t get more energy sucked because it’s somehow immune to that, so it won’t become a Purple Dwarf. It just becomes a Purple Giant. It will get mass sucked way beyond Purple Supergiant status. Rainbow Ultragiants are the rarest and largest stars. If neutron stars collide with white giants at the same time purple hypergiants and green hypergiants hit each other as well as a red hypergiant all at specific speeds, they will all fuse and become a Rainbow Ultragiant, which is on average about 20x as large as the largest hypergiants. It flashes between colors of the rainbow and generates absurd amounts of energy. It could power an entire Universe worth of civilization for the universe’s entire lifespan with only the amount of energy it produces per nanosecond.
 * -|Purple Hypergiants=
 * -|White Giants=
 * -|Black Giants=
 * -|Brown Giants=
 * -|Green Hypergiants=
 * -|Green Supergiants=
 * -|Gray dwarfs=
 * -|Green Dwarfs=
 * -|Purple Giants=
 * -|Rainbow Ultragiants=

Exclusive Particles
Sungoparticles are particles that orbit electrons. They are moderately unstable, which is unfortunate for some things. They also sometimes stabilize and occasionally when this happens, they transfer between electrons or even atoms. I don’t know why they are here. Glattoms are found on the edges of molecules. They stabilize the molecule if it’s unstable, however the problem is the way they do it is they suck up any instability, making them slightly unstable. Fortunately, they dispose of instability by removing it with deletoparticles. Eggijms are what make up Gluons. They are sticky on the edge of gluons and goopy yet slippery on the inside of Gluons. They don’t make up all of gluons, though. Some of it is preons because I don’t know. Dedosihs are found in various places. They form the Eggijms and partially the deletoparticles, and they can also be found inside sungoparticles and Glattoms. Their purpose is to balance out the traits of the particles to keep everything stable, and they do moderately well. Deletoparticles are dangerous particles that can delete things. You should be careful when working with these as they are highly unstable and become extremely unstable if you remove the Dedosihs. They delete things by making their blueprint particles scatter in all directions. This makes them very dangerous.
 * -|Sungoparticle=
 * -|Glattom=
 * -|Eggijm=
 * -|Dedosih=
 * -|Deletoparticle=

Events
Sometimes a black hole will get too big and will have to start splitting into smaller black holes all over, however these black holes get too big pretty soon and then they spit, and there is more and more splitting until black holes threaten the shelledverse. Fortunately, there is something built into reality to start filling in black holes with spacetime if there are too many. It gets this spacetime by generating it. When a Rainbow Ultragiant goes supernova, it actually creates an ultranova explosion. These are extremely dangerous as they are big enough to severely damage a nearby Megasquircleverse. Ultranovas also form extremely large nebulae. They are very rare, however, due to the rarity of Rainbow Ultragiants, so they won’t cause too many problems throughout the shelledverse. Squircleverse cores sometimes explode. When this happens, the squircleverses are destroyed and a lot of the surrounding area is, too. Strangely, these entire verses of galaxies having their core explode doesn’t do as much damage as an Ultranova. However, an Omnisquircleverse core explosion deals severe damage to the space-time continuum due to how large the explosion is. Why? Because it damages spacetime itself. Every once in a while, a large star releases lasers everywhere and turns into a white dwarf. The lasers will cause heavy damage to the surrounding area, however it will actually be beneficial for stars it hits. Anyways, laser storms are life-threatening, and also unpredictable and mysterious. Nobody knows why these occur. Also, rainbow ultragiants never cause a laser storm for some reason, but that’s probably for the best. Sometimes there are a few too many deletoparticles due to some fusions of stuff and accidentally making a lot of deletoparticles, deleting large amounts of planets. This is very rare, but it isn’t too dangerous for stars because they are mostly immune to deletoparticles due to the deletoparticles being ridiculously small in comparison.
 * -|Black Hole Pandemic=
 * -|Ultranova=
 * -|Squircleverse core explosion=
 * -|Laser storm=
 * -|Deletoparticle overload=