Space is filled with a vast «cosmic web» of strands and clumps of dark matter, which have grown from microscopic variations in the original, nearly smooth distribution dark
matter after the big bang.
Not exact matches
-- 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?
Heck,
matter didn't even start dominating until 60,000 — 70,000 years
after the
big bang.
it is your misconception of Who, what is God in the scientific theology, God is the integral forces,
matter, conciousness and all reality that exist in the universe, we humans is just part of Him
after the
big bang when he willed 13.7 billion years ago to become
matter.E = mc2.
every thing produced
after the
big bang has consciouness, its inherent to all
matter, only its level of existence corresponds to its complexity, and relating it to faith its inharent to Him.
consciousness is present in all
matter, just like gravity it is inherent and innate to everything produced
after the
big bang, only its level of existence varies with evolution, highest is that of living things, at the top is us humans because of the biological nature of our existence we evolve fastest and our brains has attained the highest level of complexity
everything came from Him
after the
big bang,
matter and cosciousness are some of the infinite.As explained, when the God particle or the Higgs boson existed immediately
matter evolved, with it the fundamental forces came into reality, with them is consciosness..
Just
after the
big bang, waves of neutrinos and other
matter raced across the cosmos.
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.
If dark
matter was born right
after the
big bang, it may resurface in the LHC — and physicists might get a glimpse.
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.
These structures, cosmologists say, originated in quantum fluctuations in the density of
matter a split - second
after the
big bang.
According to standard cosmology, dark
matter drew together under its own gravity to form small clusters shortly
after the
big bang.
«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.
Quantum fluctuations may have caused
matter to collapse into black holes
after the
big bang.
But this does a poor job of explaining why
matter triumphed over antimatter in the moments
after the
big bang.
Matter and antimatter should have been produced in equal amounts
after the
big bang.
A hidden population of black holes born less than one second
after the
big bang could solve the mystery of dark
matter
According to theory,
after the
big bang the universe was equal parts
matter and antimatter, which annihilate one another when they meet.
Although these effects exist only in the theoretical realm, the underlying equations could help us puzzle out some of the real - world properties of the hot, superdense
matter that existed right
after the
big bang.
The first stars formed along vast filaments of dark
matter that appeared relatively soon
after the
big bang, according to a new model of the universe.
It holds that in the earliest days
after the
big bang, exotic dark
matter, with just a sprinkling of normal
matter, clumped into blobs along narrow filaments.
They really have a strong reluctance to mingle with other particles, which makes them antisocial and difficult to pin down, but they are connected to such a wide range of phenomenon from the subatomic to the cosmic that they could tell us a lot about many different things, many different mysteries about the nature of
matter, about what triggers exploding stars, to what's going on in the heart of the sun, to what the universe might have been like, the conditions within seconds
after the
big bang.
Ray Jayawardhana: They are connected to such a wide range of phenomenon from the subatomic to the cosmic that they could tell us a lot about the nature of
matter, about what triggers exploding stars, to what the universe might have been like, the conditions within seconds
after the
big bang.
But recently, a survey has found several quasars — bright cores of galaxies, powered by
matter falling into a supermassive black hole — that existed less than a billion years
after the
big bang.
On 27 April a map published in the journal Nature gave scientists their most detailed glimpse yet of the primordial universe, revealing the shape of the cosmos and the distribution of
matter shortly
after the
big bang.
Physicists believe that right
after the
big bang, the Universe was made of equal amounts of
matter and antimatter.
Matter and antimatter are thought to have been created in equal amounts after the big bang, yet something has caused matter to be far more dominant than antimatter, at least in our patch of the uni
Matter and antimatter are thought to have been created in equal amounts
after the
big bang, yet something has caused
matter to be far more dominant than antimatter, at least in our patch of the uni
matter to be far more dominant than antimatter, at least in our patch of the universe.
Starting with data taken from observations of the cosmic background radiation — a flash of light that occurred 380,000 years
after the
big bang that presents the earliest view of cosmic structure — the researchers applied the basic laws that govern the interaction of
matter and allowed their model of the early universe to evolve.
According to the
big bang theory, for the first 380,000 years
after the
big bang, the expanding universe was so hot that all
matter was ionized.
Had the universe been slightly denser by one part in 1062, the expansion would have slowed and collapsed back on itself in a «
big crunch»
after 13.7 billion years (today's age of the universe according to the
big bang theory).60 Had the universe been slightly less dense by one part in 1062, «the universe would have expanded «so quickly and become so sparse it would soon seem essentially empty, and gravity would not be strong enough by comparison to cause
matter to collapse and form galaxies.61 The stretching explanation does not have this problem.
Just
after the
big bang, waves of neutrinos and other
matter raced across the cosmos.