Maybe we have been misinterpreting data all along and it actually is a very even flowing steady state universe with super novas black holes and galaxies coming and going, extending like this throughout all infinity, basically just trading off between nothingness and somethingness with oddly
behaving subatomic particles.
Not exact matches
She traces those anomalies back to a fraction of a fraction of a second after the Big Bang, when our universe was so small that it
behaved like a
subatomic particle, dominated by quantum physics.
Many models have suggested that the flow of
particles from these
subatomic fireworks produced in high - energy nuclear collisions should
behave like a gas and not a liquid.
Before the Large Hadron Collider goes hunting for sparticles, it will first test the boundaries of the standard model of
particle physics, the reigning theory of how
subatomic particles behave (see «Catch Me if You Can» by Karen Wright, Discover, July 2005).
In 1995 her colleagues showed that thousands of cold
subatomic particles can
behave like a single enormous atom, a state called a Bose - Einstein condensate.
Particles behaving oddly at the Large Hadron Collider seem to be the strongest signs yet of an unusual «
subatomic pancake» called a colour - glass condensate.
Neutrinos, like other
subatomic particles, sometimes
behave like waves.
When someone watches a
subatomic particle or a bit of light pass through the slits, the
particle behaves like a bullet, passing through one hole or the other.
Currently, the universe we live in obeys two seemingly incompatible laws — quantum mechanics, which governs the behavior of
subatomic particles; and relativity, which describes how clumps of atoms, such as humans, stars and galaxies,
behave.
One of these non-intuitive behaviors is that
subatomic particles actually
behave more like waves than like discrete
particles — a phenomenon called wave -
particle duality.