Displaced dark matter is curved spacetime

Dark matter is a supersolid that fills 'empty' space, strongly interacts with ordinary matter and is displaced by ordinary matter. What is referred to geometrically as curved spacetime physically exists in nature as the state of displacement of the supersolid dark matter. The state of displacement of the supersolid dark matter is gravity.

The supersolid dark matter displaced by a galaxy pushes back, causing the stars in the outer arms of the galaxy to orbit the galactic center at the rate in which they do.

Displaced supersolid dark matter is curved spacetime.

Astronomers Discover New Galaxy That Is 99.99% Dark Matter

A relatively large fraction of the stars is in the form of very compact clusters, and that is probably an important clue.

The more compact the cluster the greater the displacement of the supersolid dark matter connected to and neighboring the cluster, the greater the displaced supersolid dark matter pushes back and exerts pressure toward the cluster, the faster the stars in the cluster move.

Scientists Thought All Galaxies Had Dark Matter, but They Just Found One Without It

DF2 upends current theories about how galaxies form, which predict that the gravity of dark matter is necessary for early galaxies to hang together.

The reason for the mistaken notion the galaxy is missing dark matter is that the galaxy is so diffuse that it doesn't displace the supersolid dark matter outward and away from it to the degree that the dark matter is able to push back and cause the stars far away from the galactic center to speed up.

It's not that there is no dark matter connected to and neighboring the visible matter. It's that the galaxy has not coalesced enough to displace the supersolid dark matter to such an extent that it forms a halo around the galaxy.

A galaxy's halo is not a clump of dark matter traveling with the galaxy. A galaxy's halo is displaced supersolid dark matter.

This Dark Matter Theory Could Solve a Celestial Conundrum

our galaxy is swimming in a superfluid sea

Dark Matter More Ubiquitous Than We Ever Thought

dark matter is smooth, distributed more evenly throughout space than we thought

Robert B. Laughlin, Nobel Laureate in Physics, endowed chair in physics, Stanford University, had this to say:

the empty vacuum of space … is filled with 'stuff'

Laughlin’s ‘stuff’ is the smoothly distributed, strongly interacting, supersolid dark matter that fills ‘empty’ space and is displaced by ordinary matter.

Einstein: Ether and Relativity

According to the general theory of relativity space without ether is unthinkable; for in such space there would be no propagation of light

Einstein’s ether is the supersolid dark matter that fills ‘empty’ space and is displaced by ordinary matter.

the state of the [ether] is at every place determined by connections with the matter and the state of the ether in neighbouring places

The state of the supersolid dark matter at every place determined by its connections with the ordinary matter and the state of the supersolid dark matter in neighboring places is the state of displacement of the supersolid dark matter.

The Milky Way's dark matter halo appears to be lopsided

the dark matter halo of the Milky Way is dominantly lopsided in nature.

The Milky Way's halo is lopsided due to the ordinary matter in the Milky Way moving through and displacing the supersolid dark matter, analogous to a submarine moving through and displacing the water.

Offset between dark matter and ordinary matter

the gravitational potential in clusters is mainly due to a non-baryonic fluid

The center of the light lensing through the space neighboring the galaxy clusters and the center of the galaxy clusters themselves is offset due to the galaxy clusters moving through and displacing the supersolid dark matter, analogous to submarines moving through and displacing the water.

NASA's Gravity Probe B Confirms Two Einstein Space-Time Theories

Imagine the Earth as if it were immersed in honey. As the planet rotates, the honey around it would swirl, and it's the same with space and time

Honey has mass and so does the supersolid dark matter. The swirl is the state of displacement of the dark matter connected to and neighboring the Earth.

The supersolid dark matter displaced by the Earth, pushing back and exerting pressure toward the Earth, is gravity.

There is evidence of supersolid dark matter every time a double slit experiment is performed, as it is the supersolid dark matter that waves. Wave-particle duality is a moving particle and its associated wave in the supersolid dark matter.

In de Broglie's double solution theory there are two waves. There is the wave-function wave which is statistical, non-physical and is used to determine the probabilistic results of experiments. It is a mathematical construct only. It doesn't physically exist. There is also a physical wave in a “subquantic medium” which guides the particle.

NON LINEAR WAVE MECHANICS by LOUIS DE BROGLIE

Since 1954, when this passage was written, I have come to support wholeheartedly an hypothesis proposed by Bohm and Vigier.

According to this hypothesis, the random perturbations to which the particle would be constantly subjected, and which would have the probability of presence in terms of [the wave-function wave], arise from the interaction of the particle with a “subquantic medium” which escapes our observation and is entirely chaotic, and which is everywhere present in what we call “empty space”.

De Broglie’s “subquantic medium” is the supersolid dark matter that fills 'empty' space.

Interpretation of quantum mechanics by the double solution theory - Louis de BROGLIE

When in 1923-1924 I had my first ideas about Wave Mechanics I was looking for a truly concrete physical image, valid for all particles, of the wave and particle coexistence discovered by Albert Einstein in his "Theory of light quanta". I had no doubt whatsoever about the physical reality of waves and particles.

any particle, even isolated, has to be imagined as in continuous “energetic contact” with a hidden medium

For me, the particle, precisely located in space at every instant, forms on the v wave a small region of high energy concentration, which may be likened in a first approximation, to a moving singularity.

the particle is defined as a very small region of the wave

Particles of ordinary matter move through and displace the supersolid dark matter, causing it to wave. In a double slit experiment it is the strongly interacting dark matter that waves.

In the following video the vibrating silicon substrate represents the chaotic supersolid 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.

Is This What Quantum Mechanics Looks Like?

In a double slit experiment the particle always travels through a single slit and the associated wave in the supersolid 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.

It is the chaotic nature of the supersolid dark matter which causes the Casimir effect.

Water wave analogue of Casimir effect

It is the chaotic nature of the dark matter which leads to the probabilistic results of experiments.

In the following articles the fluid is the chaotic supersolid dark matter.

Fluid mechanics suggests alternative to quantum orthodoxy

The fluidic pilot-wave system is also chaotic. It’s impossible to measure a bouncing droplet’s position accurately enough to predict its trajectory very far into the future. But in a recent series of papers, Bush, MIT professor of applied mathematics Ruben Rosales, and graduate students Anand Oza and Dan Harris applied their pilot-wave theory to show how chaotic pilot-wave dynamics leads to the quantumlike statistics observed in their experiments.

When Fluid Dynamics Mimic Quantum Mechanics

If you have a system that is deterministic and is what we call in the business ‘chaotic,’ or sensitive to initial conditions, sensitive to perturbations, then it can behave probabilistically,” Milewski continues. “Experiments like this weren’t available to the giants of quantum mechanics. They also didn’t know anything about chaos. Suppose these guys — who were puzzled by why the world behaves in this strange probabilistic way — actually had access to experiments like this and had the knowledge of chaos, would they have come up with an equivalent, deterministic theory of quantum mechanics, which is not the current one? That’s what I find exciting from the quantum perspective.