Naked Science Forum
On the Lighter Side => New Theories => Topic started by: msetlur on 09/04/2017 15:46:43
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There is evidence of the superfluid dark matter every time a double slit experiment is performed, it's what waves.
Superfluid dark matter fills 'empty' space, strongly interacts with and is displaced by ordinary matter. What physicists mistake for the 'clumpiness' of dark matter is actually the state of displacement of the superfluid dark matter.
'The Milky Way's dark matter halo appears to be lopsided'
http://arxiv.org/abs/0903.3802
the emerging picture of the dark matter halo of the Milky Way is dominantly lopsided in nature.
The Milky Way's halo is not a clump of dark matter traveling along with the Milky Way. The Milky Way's halo is lopsided due to the ordinary matter in the Milky Way moving through and displacing the superfluid dark matter, analogous to a submarine moving through and displacing the water.
What ripples when galaxy clusters collide is what waves in a double slit experiment, the superfluid dark matter which fills 'empty' space.
Superfluid dark matter displaced by ordinary matter relates general relativity and quantum mechanics.
The superfluid dark matter is likely a sea of massive dark photons which ordinary matter moves through and displaces.
'Glenn Randall talks about dark matter'
https://asunow.asu.edu/20160624-glenn-randall-talks-about-dark-matter-popular-mechanics
dark matter might interact with itself via some yet unknown dark force ... the particles could be something we call dark photons ... the dark photon would have mass
The sea of massive dark photons displaced by ordinary matter is the quantization of gravity.
In a double slit experiment it is the superfluid dark matter that waves.
In the following video the silicon bath represents the superfluid dark matter. In the video, in the double slit experiment example, the particle travels through a single slit and the associated wave passes through both.
In a double slit experiment the particle always travels through a single slit and the associated wave in the superfluid dark matter passes through both. As the wave exits the slits it creates wave interference which alters the direction the particle travels as it exits a single slit. Over time the particles form an interference pattern. Strongly detecting the particle exiting a single slit destroys the cohesion between the particle and its associated wave, the particle continues on the trajectory it was traveling and does not form an interference pattern.
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I guess you'd have to find a way of performing the double slit experiment entirely inside a large chunk of glass. If your idea is correct there should be no superfluid then to interfere (or perhaps much less), and you should get only particle-like behaviors. I'm skeptical that this will be the case, but it'd be interesting to try.
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I guess you'd have to find a way of performing the double slit experiment entirely inside a large chunk of glass. If your idea is correct there should be no superfluid then to interfere (or perhaps much less), and you should get only particle-like behaviors. I'm skeptical that this will be the case, but it'd be interesting to try.
There are no such things as virtual particles, with mass, popping into and out of existence out of nothing. What are mistaken for virtual particles, with mass, popping into and out of existence out of nothing is the superfluid dark matter which fills 'empty' space. Watch the following video starting at the 1:52 mark to see a visual representation of the superfluid dark matter which exists where the quarks do not. Where the quarks exist the superfluid dark matter has been displaced from those locations.
I'm not sure if double slit experiments can be performed in glass. However, the 'empty' space in the glass is filled with superfluid dark matter.