You have probably heard of black holes already. If not, it’s time you do. The black hole is one of our known astral plane beings, which play an important role in our space travel. But a black hole also has something more than that: it has a dark matter surrounding it. In fact, the black hole may be so dense that even light cannot escape from it, or if it does escape, it will appear very dim and distorted.
Simply put, a black hole is simply a region in space where gravity is extremely strong enough that absolutely nothing, including light, can escape from it. Unlike a normal horizon line, a black hole’s event horizon is never seen by humans on the surface of the earth because its gravitational pull is too great. As a result, even if a spacecraft were designed to penetrate these gravitational wells, it would utterly fail to do so, as it would be completely blocked by their very denseness. Also, black holes cannot be detected with the technology we have available today, such as with the help of a satellite or by detecting reflected sunlight.
Another interesting thing about black holes is that we actually know how they form. Since we know that they are not governed by a vacuum like the solar system, it is believed that they formed in a large empty space similar to our own solar system. One fascinating theory on this subject is that the supermassive Black Hole (SMBH) is a ring, or rather a halo, around a supermassive black hole. What makes this theory so fascinating is that it suggests that there are two different kinds of black holes, although both are essentially singularities. In other words, there is a “normal” black hole that is surrounded by a “normal” supermassive black hole. The reason this theory is so fascinating is that we don’t actually know what the composition of such a space, or what its relationship with other stellar objects is.
It was also once believed that black holes were nothing more than the product of general relativity. Even though this concept was thoroughly discredited in the 1970s due to the advent of quantum mechanics and the development of the Standard Model of particle physics, it did not go away completely. For the last few decades, many theories have been developed that still attempt to show that there is some independent structure behind black holes. Among the most widely accepted of these theories is the idea that there are two different kinds of black holes, which are ones that are near or very near to a black hole, and those that are far away from it. In order to account for the accelerating motion that we see in black holes, General Relativity is using to describe their relationship with a stellar mass.
If a black hole has a very strong gravitational field, it would take light years to travel from one side of it to the other. However, if you were to bring an extremely heavy object to a close proximity to it (i.e. send a probe onto a moon like orbit around it), it would burn up (collide) with the surrounding gas, creating a shockwave, which is what we call a singularity. If the object is extremely heavy or very compact, it would collapse in on itself creating a much bigger black hole. A normal G-suit, which is a suit consisting of a T-shirt and some pants, would only be able to contain a few grams of weight, so it cannot be called a singularity, even by some scientists.
The only real way to know for sure if a black hole will create a “singular” event is to visit one and make sure you can watch it with the proper equipment. If the object is too small to produce a visible event horizon, or if it recedes too quickly from your view, it could be an M-hole. An M-hole is also not very common, as it is usually associated with high-energy stars and very dense (and therefore rare) comets. With an M-hole, space is distorted slightly, thus creating a slight movement in the gravitational field – but that’s about all it will do. The other two types are not worth mentioning.