Black Hole Theory

[rzr]

So, in the late 1970's George Lucas had the revelation of Star Wars. His beloved characters wielded deadly weapons made of light known as Lightsabers. Obviously, such a weapon is preposterous. But, after studying, in depth, black holes and photons, I've come to a bit of a theory. Perhaps the creation of Lightsabers isn't as far fetched as one may think. Furthermore, the ability to transport oneself to other positions iin the natural universe is also not too out of the realm of possibility.
To understand a black hole you must first be able to understand how it is formed. Typically, a black hole is formed when a star, larger than our sun, collapses. Or a body of matter at such size, as well. How does something larger than our sun, typically 7 times larger, collapse? Good question. At the center of all giant masses is where the gravitational pull is derived. The center of the star is, at all times, pulling the outer star in towards it at such a great force. Eventually, the star is pulled so far into itself by its own gravitational pull that it is so dense that it collapses. In fact, a simple tablespoon of this matter can way approximately 5.5 tons. This matter is now pulling all objects within its gravitational pull towards it, thus forming a black hole. A black hole can, in theory, evaporate, but that's much more complicated.


So, the question becomes how to destroy a black hole. Well, how do you cancel out the charge of an electron? Expose it to an equal, but opposite, charge of a proton. How do you eliminate a powerful acid? Expose it to a base of equal, but opposite, strength. So, to eliminate a black hole you must expose it to an equal, but opposite, amount of matter. What the heck is this called? A white hole. No, I'm not kidding you. Though black holes do exist in nature, white holes, to our knowledge, do not. However, they are a perfectly logical and arguable solution to a black hole. Now, what is a white hole? Well, in a black hole matter is swallowed, densened, and time is slowed down. Yes, time is literally slowed down inside of a black hole. So, in a white hole matter is spit out, expanded, and time is sped up. By now you're probably thinking to yourself that I'm rambling and this has nothing to do with my original statement. Well, keep reading.
Now, what is a wormhole? A wormhole is where a black hole and a white hole interact.


So, a black hole acts as a door. You go through the door, but not to the other side. So, you're in the first part of the door frame (this door has its own gravitational pull, haha). This is the part of the black hole. Now, the white hole, in essence, spits you back out – placing you on the other side of the door. So, basically, you go into the black hole and come out of the white hole due to events I already explained. Given that these holes are, as previously stated, 7 times larger than our sun, you could easily travel great distances in little to no time at all. The only problem with this is here:

As stated, a white hole is the exact opposite of a black hole. Well, what direction does time travel in a black hole? Forward. Meaning, in a white hole, time would travel backwards. Therefore, going through a wormhole would not only bring you to another part of the universe, but also backwards into time, given that you exit the time declining white hole. This begs the question, well, if you've gone backwards in time then you're back in a previous place, not a new one. So, how does this work? Well, just as some scientists theorize that time is slowed down in a black hole, some theorize is speeds up (this being the more logical solution to several factors, including the one I'm describing here). But, you'll next ask me how do I know this? Eh, as tiresome as it is explaining that to you, I'll have to in order for you to understand how to prove my hypothesis true.
There is a particular region outside of the black hole known as the 'horizon'. So, let's imagine you and your friend are sitting in a spaceship outside of the horizon. Well, luckily, you're outside of it because on or inside the horizon is the point of which the central gravitational pull is too strong for you to escape. Now, we'll imagine that you are so brave and noble that you have decided to venture inside the black hole, leaving your friend outside. Well, you're about to be ripped to shreds, too bad your friend will never be able to see this happening to you. See, the inside of the black hole is pulling everything towards it because of the gravitational pull. Nothing can travel faster that its pull. Nothing. Including light. This means that, even though light can travel into the black hole, it cannot travel out. So. You can see your friend sitting precariously perched outside the horizon, but they cannot see you. Now, you're not necessarily being pulled in at light speed. In fact, depending on the size of the black hole, it could be very slow. See, the gravity isn't so strong just yet to pull you right down, especially as a whole. The closer you get to the center, the more you will feel the gravity. But, remember how large I told you a black hole is? Imagine how long it takes to get to the center. Now, we'll imagine you're still falling into the black hole and you've just reached a certain gravitational force that you feel it. Well, regardless, you're not going to -completely- feel it. In fact, at first it'll only be your feet. Progressively, your legs and what-not will also feel the pull. They will, quite literally, bu pulled from your body. Like I said, torn to shreds. But, wait, what does all this have to do with time? Well, time is a concept of movement. How much time does it take for object A to reach location B (at which time event X occurs)? Or, how long does it take for event Y to happen? Well, any event can only occur with an object. The object is, theoretically, moving. Moving to location M. Object C takes Z (Z=time) to reach location M. Location M, also being another object. All of these variables are a concept of time. So, what happens in a black hole? Matter is moving exponentially quick (though it would feel slow to you if it were happening). So, with all these objects moving so quickly, time is sped up.
Back to the wormhole. So, we were asking how you could come out of a wormhole in a different place even though the exit of the wormhole involves time rolling backwards. Well, if the time in the black hole section of the wormhole is sped up, that means the exact opposite is happening in the white hole, therefore canceling each other out, causing you to arrive at the exact same moment that you entered the black hole.


Thus, assuming a white hole can be created, proving one can travel across space and time in near light speed, if not faster. But, wait. This doesn't completely prove my hypothesis true. Why not? Because there's no such thing as a white hole! So, given that we now know how to create a black hole, how do we create a white hole? Well, you'd most likely die in the process. But, really, let's create one. So, we know that a white hole is the exact opposite of a black hole, and we know you can create a black hole by a star dying out. Wouldn't that mean that by creating a star you would create a white hole? But, how do you create a star? You need enough concentrated energy and matter for the energy to become heat and engulf the matter. But, when you do that you create a star, not a white hole. So, what's the -real- opposite of a black hole creation? Well, the star doesn't technically “die out.” Its gravitational pull becomes so great that is sucks itself into a dense ball. So, the opposite of that would be to create an object with the exact opposite force as gravity itself. But, there is no such existent force in the natural universe. Unless you count magnetism, but that means you'd need something to attract it. However, let's assume this force, now being the fifth force in the universe, exists. This means we have now an object that pushes all matter away from it, in essence, spitting it out. But, is that not what a while hole does? So, in theory, we have now created a white hole. With our previously existing black holes and our newly formed white holes, we can now create a wormhole, allowing my theory of space and time travel to be true. But, wait. I never said anything about time travel. Well, this is another theory I'm working on. Since black holes can be any variation of size, this means so can a white hole. So, what would happen if we placed a white hole and black hole together, but of different sizes? Meaning, depending on which hole we allowed to be the larger, time would flow in that direction quicker. The problem with this is that if you enter a black hole (since you obviously can't enter the white hole as its pushing you away) that has a force greater than that of the white hole, how do you get out? You don't. Unless you can now travel faster than light, assuming whatever speed faster than light you achieve -can- actually escape the black hole, you are physically stuck in the black hole for all of eternity (or until the white hole gains more force that the black hole). Sadly, this means it is impossible for you to travel -forward- in time. However, this does not mean it is impossible to travel backwards in time. In fact, it is quite possible to do so. As long as the white hole has a greater force than the black hole. You will go into th black hole and time will speed up. You will then go into the white hole and time will reverse. However, since time is more powerfully reversing than going forward, you will now be back in time. So, there you go, you can now travel into the past. The problem is, you can't leave. So, let's find a way for you to leave. I'm going to use the equation 1b:2w to represent what I'm trying to describe. The numbers being a theoretical force measurement. B = black hole, w = white hole. So, the wormhole you're entering has a force of 2b:3w. We need a way to go past 3w. Well, 3w>2b, and light cannot pass 2b. So, we need to develop a way for you to travel faster that the speed of light. Well, good luck with that, I'm not even going to attempt getting into that. Anyway, assuming we have this capability, you can penetrate 3w. If you can travel faster that 3w, you can travel faster than 2b. We now have a way for you to go through the white hole side of a wormhole. So, we still need to be able to travel forward in time. Well, as it stands w>b. So, let's start anew where b<w. Using the reverse of the original equation we have 2b:1w. Meaning, now that we have a way to travel faster than 2b, we can penetrate the black hole and pass through the white hole with 1t, t being time measurement, remaining. T being the forward of time, you've now accelerated in time, thus proving time travel, in both directions, is possible.


But hey, we seem to have gotten a bit side tracked from our original light saber theory. This will actually take a lot less time to describe. Unless we're in a black hole, then it may take more. Haha, science joke. Anyway, how did I say a black hole is formed? By pulling its own mass into the center to a point where it is so dense that even light cannot escape it. So, if we can find a way to make light itself that dense we could use it to move things or even 'cut' them. The first task is too make light dense. Well, what is light comprised of? Photons. A simple particle, but lots of them. So, in theory, we take several photons. But, how do we make them dense. Well, I suppose we first need to create a black hole. So, we create our black hole and release our photons into it. How do we get them back out without getting ourselves trapped? Well, now we need to create a white hole with equal, but opposite, force of the black hole. Okay, we create it. This white hole now creates a worm hole, which brings our photons off to somewhere far off in the universe. Let's just pretend there's some little guy waiting for the photons at the other end of the worm hole to collect our newly densened photons. But, hold up, do you see the little problem we now have? The black hole may make the photons more dense, but the white hole will make them expand and cancel out the densening. So, how do we make our photons dense and get them back without them expanding or being lost in the black hole? We need our little mechanism that can travel faster than the speed of light to go into the black hole and retrieve them.


Finally, we take our dense photons and concentrate them into a specific direction. Not a problem. Being as dense as they now are, they can move objects as large, if not larger, than planets. But, that's just assuming there's no way to stop them from continuing on and on forever until they collide with and force an object out of, their way. So, we're faced with yet another little obstacle. How to stop the photons from continuing on forever. We need a way to cap them. Meaning, an object more dense than the photons themselves. So, we put our photons through a 1b and the cap through a 2b. Fair enough. There's just one issue here, and this one cannot be logically resolved. The photons weigh more than our sun. The cap weighs twice that. There's no possible way for us to hold or carry such a device. My hypothesis was indeed, false. However, after reflecting this much and putting so much time, effort, and thought into the theory, it was worth it.

Oh, and yes, I did draft this up all on my own. I want contradictions, agreements, and an edit would be nice.