-- seeing energy can not be created nor destroyed, then before, during and
after the big bang energy was the only thing there was, so why wouldn't 100 % of energy in this vast universe be capable of creating the minut amount of matter that fills it?
Not exact matches
Although science can state a great deal about what followed
after the
big bang, it can not in fact explain how «something» (the
energy of the universe compressed into a volume the size of a golf ball) arose from nothing beforehand.
To sum up in lay terminology,
after the first microseconds of the
big bang, there was an amorphous
energy field.
Since then, the Steady State Theory has been disproven, and the
Big Bang Theory has been shown to be correct, vindicating a form of «Creationism», which not only explains «let there be light» (the early universe was dominated by radiation — light), but explains of separation of light and darkness — the decoupling era, about 300,000 earth years after the big bang, when the universe cooled below the ionization energy of hydrogen, allowing it to become transparent for the first ti
Big Bang Theory has been shown to be correct, vindicating a form of «Creationism», which not only explains «let there be light» (the early universe was dominated by radiation — light), but explains of separation of light and darkness — the decoupling era, about 300,000 earth years
after the
big bang, when the universe cooled below the ionization energy of hydrogen, allowing it to become transparent for the first ti
big bang, when the universe cooled below the ionization
energy of hydrogen, allowing it to become transparent for the first time.
Neutrinos that filled the universe a mere second
after the
big bang make up a third «dark» component of the cosmos, alongside dark matter and dark
energy.
It's supposed to be the «gold standard» of evidence supporting the standard model of cosmology — including dark matter, dark
energy and the exponential expansion
after the
big bang known as inflation.
Observations show that the universe is in fact flat (there is just enough matter to slow its expansion but not to halt it), has zero total
energy and underwent rapid inflation, or expansion, soon
after the
big bang, as described by inflationary cosmology.
«If we know the initial amounts of stuff in the universe, such as dark
energy and dark matter, and we have the physics correct, then you can go from a measurement at the time shortly
after the
big bang and use that understanding to predict how fast the universe should be expanding today,» said Riess.
So far, all the attention has focused on schemes that come into play under the high -
energy conditions that existed just
after the
big bang.
The idea is that by sifting through the debris from these collisions, physicists can identify short - lived, exotic particles and probe the high -
energy conditions that existed in the crucial first instants
after the
big bang.