Why it's so hard to see higher dimensions?

When black hole forms in a supernova explosion that explosion packs its material to form called singularity. The black hole gets all its energy in that explosion. And after that, the singularity starts to turn into wave movement. 

That means: the black bole sends radiation with so special wavelength. That we cannot see that wave movement.

 One of the reasons why we cannot see the black hole behind the event horizon is that black holes could send wave movement in a way unknown to us. In some theoretical models, black holes send monotonic wave movement where the energy level is the same all the time. 

In normal wave movement, there is like hills and valleys in that electromagnetic radiation. But there is the possibility that a black hole sends Hawkings radiation in the same way all the time.  So the only change in the energy level of that radiation could form when a black hole loses its mass when it turns to Hawking's radiation. Because there are no short-term changes in that radiation that thing is hard to detect. 

The image above: Curve A introduces how a black hole sends Hawking's radiation. The model is that the curve is straight down without internal changes. If that model is true, it explains why it's so hard to detect that Hawking's radiation that causes that black holes are losing their mass. Curve B: The curve below that straight line introduces the changes in energy level in a  wave movement the source is a regular particle. 

The superstring theory about higher dimensions is a fascinating thing. There are theories about the higher dimensions and one of them is that black holes are four-dimensional spaces. The black hole's energy level is so high. That universe turns to four-dimensional. So black hole presses particles to form, that we cannot see it. And there are theories that higher dimensions exist but they are so small that we cannot see them. 

In some models, the higher dimension is the energy level where the particle stops interacting with other particles. This thing happens when a particle's size turns smaller and smaller when its energy level rises. And sooner or later the particle turns so small that it cannot affect objects in the third dimension. So the size of the wave movement is so small that it cannot cause so large area effect on other particles. The key element of string theory is all material forms of superstrings. Those superstrings are like rolls in energy fields. And there is the possibility that some higher dimensions exist in the superstrings. 

Can we sometimes interact with higher dimensions? If the Higgs field is like a membrane between three- and four-dimensional space, there is a possibility that sometimes there is forming holes in that membrane. The idea is that if Higgs Boson has the precise right energy level it can collapse precisely a certain way. And then that collapsing Higgs Boson could form a follow-up particle that makes a hole in the membrane. 

That hypothetical Higgs Boson's follow-up particle would have a shorter life cycle than Higgs Boson. And that makes proof of its existence almost impossible. But the thing is that this membrane between dimensions should be the Higgs Field. There is the possibility that there are also other electromagnetism fields that are not seen yet. And Higgs Field is the only candidate for that field. So maybe we ever cannot prove or model the higher dimensions the way that it satisfies the scientific world. 

Image: https://scitechdaily.com/comprehensive-overview-of-progress-achieved-in-the-field-of-quantum-teleportation/