Author(s)

Alexander Alecsandrovich Antonov

Independent Researcher, Kiev, Ukraine.

It is currently a generally accepted opinion in astrophysics that the phenomenon of dark matter and dark energy can be explained only by existence of microcosm contents unknown to us. This assumption seems to be quite reasonable, since the Monoverse hypothesis following from the postulate about non-exceedance of the speed of light in the special theory of relativity, leaves no place for dark matter and dark energy in macrocosm. However, the assumption is erroneous, as dark matter and dark energy are actually invisible parallel universes in six-dimensional space, as shown in the article. Therefore, they can be detected only during research of macrocosm. Research of the phenomenon of dark matter and dark energy is presented in the article. Moreover, it is performed using previously unknown experiments that have allowed proof of general scientific principle of physical reality of concrete imaginary numbers. In the special theory of relativity, this principle has refuted the postulate of light speed non-exceedance. It has also allowed adjustment of relativistic formulas. It follows from the adjusted relativistic formulas that we live in a hidden Multiverse. The article explains the nature of mutual invisibility of parallel universes of the hidden Multiverse and proves verifiability of the hypothesis of the hidden Multiverse. The hypothesis has explained the nature of dark matter and dark energy as well as given an idea where antimatter is and why it does not annihilate with matter. It has also explained where tachyons are and why they do not violate the principle of causality. According to the hypothesis, the hidden Multiverse is connected to other Multiverses through portals, forming dark space. Multiverses of dark space together with the hidden Multiverse form a Hyperverse.

Imaginary Numbers, Dark Matter, Dark Energy, Dark Space, Multiverse, Hyperverse

Antonov, A. (2018) Discovery of Dark Space. Journal of Modern Physics, 9, 14-34. doi: 10.4236/jmp.2018.91002.