Answer and Explanation: The first thing that would happen to you if your body was transformed into the dark matter is that you would no longer be connected to anyone or anything at all, and anyone viewing you would immediately see you vanish.
In fact, the dark matter impact would generate so much heat that it would tunnel through body tissue as a flesh-melting plasma plume, the study authors reported. Most physicists hunting for dark matter are searching for particles smaller than atoms.
The nuclear forces that hold your nuclei and protons together would vanish; the electromagnetic forces that caused atoms and molecules to stay together (and light to interact with you) would disappear; your cells and organs and entire body would cease to hold together.
Dark matter is the collective term given to subatomic particles which are capable of altering a human's biological structure to turn them into meta-humans and allow them to develop superpowers.
It passes through all the matter in the Universe, including human beings, as though it weren't there at all. There are, to the best of our knowledge, no collisions or interactions other than its effects on curving spacetime.
Weaponized dark matter was dark matter that had been made into a weapon by converting it into a small sphere that could rip molecules at a subatomic level, thus killing an individual.
In fact, recent estimates put dark matter as five times more common than regular matter in our universe. But because dark matter does not interact electromagnetically, we can't touch it, see it, or manipulate it using conventional means.
No one seems to have been killed by speeding blobs of dark matter. Dark matter is an invisible substance that's nearly everywhere in the universe. Scientists don't yet know what dark matter is. But the fact that it hasn't killed anyone puts limits on how large and deadly dark matter particles can be, scientists say.
Dark matter particles can penetrate all other forms of matter, which means that they may even be able to traverse right through our planet without losing any energy whatsoever. On the other hand, their impact with ordinary matter that Earth is comprised of may hamper them slightly, resulting in a loss of energy.
Dark matter doesn't interact with electromagnetic radiation or light as ordinary matter that surrounds us on a day-to-day basis does. This makes dark matter virtually invisible, but thanks to the fact it does interact with gravity, astronomers can infer its presence.
The term dark matter was coined in 1933 by Fritz Zwicky of the California Institute of Technology to describe the unseen matter that must dominate one feature of the universe—the Coma Galaxy Cluster.
But it is an important mystery. It turns out that roughly 68% of the universe is dark energy. Dark matter makes up about 27%. The rest - everything on Earth, everything ever observed with all of our instruments, all normal matter - adds up to less than 5% of the universe.
Dark matter can be trapped inside massive objects, and much of it may be closer to the surface of stars and planets than we realised. On Earth, there may be more than 10 trillion dark matter particles in each cubic centimetre of the planet's crust.
Dark matter is completely invisible. It emits no light or energy and thus cannot be detected by conventional sensors and detectors. The key to its elusive nature must lie in its composition, scientists think.
Understanding dark matter is important to understanding the size, shape and future of the universe. The amount of dark matter in the universe will determine if the universe is open (continues to expand), closed (expands to a point and then collapses) or flat (expands and then stops when it reaches equilibrium).
Without dark matter, the joint effects of stellar winds and ultraviolet radiation would impart such a strong “kick” to the surrounding matter that it wouldn't just get blown back into the interstellar medium, but would become entirely gravitationally unbound from the massive star cluster that just formed.
In particular, we have come to realize that without dark matter, our universe would look nothing like the way it does now. There would be no galaxies, no stars, no planets, and therefore, no life. This is because dark matter acts as the invisible skeletal structure that holds up the visible universe around us.">
Dark matter is five times more prevalent than ordinary matter. It seems to exist in clumps around the universe, forming a kind of scaffolding on which visible matter coalesces into galaxies. The nature of dark matter is unknown, but physicists have suggested that it, like visible matter, is made up of particles.
We've never been able to directly detect dark matter in any form, but we know it exists through its effects on the universe, especially through the orbital velocities of stars and gravitational lensing of light around "invisible" objects.
Scientists have not yet observed dark matter directly. It doesn't interact with baryonic matter and it's completely invisible to light and other forms of electromagnetic radiation, making dark matter impossible to detect with current instruments.
About 20% of the matter in galaxies is visible or baryonic: subatomic particles like protons, neutrons and electrons. The other 80%, referred to as “dark matter”, remains mysterious and unseen. In fact, it may not exist at all. “Dark matter” is just a hypothesis.
The Higgs boson is the God particle. It is an elementary particle in the Higgs field. It is found in the Higgs field. Dark matter is not the same as the Higgs boson.
But over the past half-decade or so, some researchers have become more open to an older idea: Dark matter consists of primordial black holes (PBHs) that emerged from the Big Bang.
Because space isn't curved they will never meet or drift away from each other. A flat universe could be infinite: imagine a 2D piece of paper that stretches out forever. But it could also be finite: imagine taking a piece of paper, making a cylinder and joining the ends to make a torus (doughnut) shape.