The theory that the universe is expanding, expanding, and expanding has been a hot topic of debate for decades, with many scientists expressing doubts about its validity.
Now, a new theory has been found to make it easier to explain the expansion of the universe and the existence of dark matter, a mysterious substance that interacts with and absorbs light from the universe.
It also holds the promise of opening up the search for dark matter that is elusive in existing cosmology.
The new theory was found by physicists at the Walden University in Germany, and was presented in a paper published on October 29 in the journal Nature Physics.
The theory is based on the idea that the first two and a half billion years of the Big Bang, the universe’s creation, were the moment when the universe was first compressed and then expanded.
The universe, in other words, came into being.
In a universe with no dark matter or inflationary inflation, this expansion would have occurred in just a few minutes.
The result is that the expansion is thought to be a process in which energy, known as gravitational field, is released into space, which can then be detected and measured.
It is a process known as cosmological constant, which means that it changes over time.
As the universe expands, the gravitational field is weaker and this allows more light to be reflected back into space.
When the universe stops expanding, the amount of light reflected is smaller, which is the same as a black hole, which creates an object called a blackbody.
These two processes create a vacuum that allows particles and their gravitational fields to escape from the surrounding matter.
The two processes then interact and eventually, in the final stage, the blackbody disappears.
When you think about the history of the cosmos, that is what has happened.
This is what makes this theory so exciting.
The expansion of a black body is a phenomenon that would have happened in the distant past.
The most common theories of the expansion say that it started with a big bang.
This means that the very first mass of matter in the universe, known to scientists as dark matter in its raw form, has to have come from something that has a lot of mass.
In the process of the dark matter to escape, it has also had to be able to emit some energy.
So, the process is the key to how the universe has grown and evolved.
The dark matter is a gas of unknown composition, but the process that makes it invisible has also been observed by a handful of cosmologists.
If the process can be understood, the discovery of dark energy could mean that we are able to find more evidence of dark stuff in the cosmos.
There are three main questions that have yet to be answered about dark energy, which have baffled cosmologist for decades.
The first question is how do we get the dark energy?
The first answer was found in the early 20th century, when physicist Stephen Hawking suggested that there must be something about the early universe that made it able to produce the dark mass, which would then explain the universe we see today.
However, it turned out that it was the dark gas that produced the mass.
The gas is a mixture of atoms and neutrons that is believed to have formed around the Big Crunch.
In fact, it was also found in a black box that had been used to study the collapse of galaxies, but it had no mass.
It was only when the Big Boy was found that astronomers started to look at the dark material that had to exist for the universe to be big enough for the Big Brother to escape.
Now this theory has some problems.
For one thing, it is based only on what was observed during the Big Break.
Scientists do not know how much the universe cooled during the event and whether dark matter was present.
For another, it requires a dark matter particle that is invisible to telescopes and requires a mass that is very small.
It turns out that dark matter can’t be produced in the form of dark gas, which explains why there is no dark energy.
The third and final question is: where is the dark stuff?
The discovery of the first dark matter had a huge impact on cosmology, but has not been followed up on to the same extent as the first.
In some ways, the latest discovery is a step in the right direction.
However the latest work does not fully solve the Big Questions about the universe as a whole, such as what the first mass is, how it has changed since then and whether it is still there.
It may not answer all of the questions.
The researchers now want to understand the physics behind the matter in our universe, and what could make it so dense and massive.
This could also help solve some other questions about dark matter.
But the latest findings still have to be validated in a lab.
It will take years of research before a final answer is achieved.
If scientists can find a way to test the theory, then it could be the answer to one