4498 - DARK MATTER - what is it?

 

-    4498  -     DARK  MATTER  -  what is it?  -    Dark matter is the mysterious stuff that fills the universe but no one has ever seen.  Roughly 80% of the mass of the universe is made up of dark matter but what is it?   Scientists have never seen it.    We only assume it exists because, without it, the behavior of stars, planets and galaxies simply wouldn't make sense.

----------------------------------------  4498    -    DARK  MATTER  -  what is it?

-   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.

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-   Visible matter, also called “baryonic matter”, consists of baryons which are an overarching name for subatomic particles such as protons, neutrons and electrons. Scientists only speculate what dark matter is made of. It could be composed of baryons but it could also be non-baryonic, that means consisting of different types of particles.

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-    Most scientists think that dark matter is composed of this non-baryonic matter. The lead candidate, “WIMPS” (weakly interacting massive particles), are believed to have ten to a hundred times the mass of a proton, but their weak interactions with "normal" matter make them difficult to detect.

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-     “Neutralinos”, massive hypothetical particles heavier and slower than neutrinos, are the foremost candidate, though they have yet to be spotted.

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-   “Sterile neutrinos” are another candidate. Neutrinos are particles that don't make up regular matter. A river of neutrinos streams from the sun, but because they rarely interact with normal matter, they pass through Earth and its inhabitants.

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-   There are three known types of neutrinos; a fourth, the “sterile neutrino”, is proposed as a dark matter candidate. The sterile neutrino would only interact with regular matter through gravity.

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-   One of the outstanding questions is whether there is a pattern to the fractions that go into each neutrino species.  The smaller “neutral axion” and the “uncharged photinos”,  both theoretical particles, are also potential placeholders for dark matter.

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-    There is also such a thing as “antimatter”, which is not the same as dark matter. Antimatter consists of particles that are essentially the same as visible matter particles but with opposite electrical charges. These particles are called antiprotons and positrons (or antielectrons).

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-    When antiparticles meet particles, an explosion ensues that leads to the two types of matter canceling each other out. Because we live in a universe made of matter, it is obvious that there is not that much antimatter around, otherwise, there would be nothing left. Unlike dark matter, physicists can actually manufacture anti-matter in their laboratories.

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-   Does dark matter exist?  We don't know! What we do know is that if we look at a typical galaxy, take account of all the matter that we see (stars, gas, dust) and use Newton's Laws of Gravity and motion (or, Einstein's General Relativity), to try to describe the motions of that material, then we get the wrong answer. The objects in galaxies (nearly all of them) are moving too fast. There should not be enough gravity to keep them from flying out of the galaxy that their in. The same thing is true about galaxies moving around in clusters.

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-   There are two possible explanations:

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------   1. There is more stuff (matter) that we don't see with our telescopes. We call this “dark matter”.

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-------  2. Newton's laws and even GR are wrong on the scale of galaxies and everything bigger. This idea is usually called “modified gravity” (because we need to modify GR) or Modified Newtonian Dynamics (MOND).

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-    Mostly, cosmologists believe that the answer is that the behavior of galaxies is explained by dark matter. Why? Partly. because it has been very hard to write down a successful theory of MOND or modified gravity. And partly because it turned out that when we turned our microwave telescopes to look at cosmic background radiation (CMB), the light from the early universe, it turned out that, according to GR, the same amount and type of dark matter was also required to explain the behavior of the sound waves that traveled in the universe when it was less than 500,000 years old, and whose imprints we are able to see. Modified gravity struggles to provide a unified explanation across all these systems, galaxies, clusters of galaxies, the universe.

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-   If dark matter exists, it must have mass. Massless dark matter would not behave in ways that solve the problems that dark matter addresses.   The two things we know for sure about dark matter (assuming it exists), is that it exerts gravity (has mass) and that it moves slowly (compared to the speed of light). 

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-    If we cannot see dark matter, how do we know it exists? The answer is gravity, the force exerted by objects made of matter that is proportional to their mass. Since the 1920s, astronomers have hypothesized that the universe must contain more matter than we can see because the gravitational forces that seem to be at play in the universe simply appear stronger than the visible matter alone would account for.

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-    Motions of the stars tell you how much matter there is.   Astronomers examining spiral galaxies in the 1970s expected to see material in the center moving faster than at the outer edges. Instead, they found the stars in both locations traveled at the same velocity, indicating the galaxies contained more mass than could be seen.

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-    Studies of gas within elliptical galaxies also indicated a need for more mass than found in visible objects. Clusters of galaxies would fly apart if the only mass they contained was the mass visible to conventional astronomical measurements.

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-   Different galaxies seem to contain different amounts of dark matter. In 2016, a team found a galaxy called “Dragonfly 44”, which seems to be composed almost entirely of dark matter. On the other hand, since 2018 astronomers have found several galaxies that seem to lack dark matter altogether.

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-   The force of gravity doesn't only affect the orbits of stars in galaxies but also the trajectory of light.   Albert Einstein showed in the early 20th century that massive objects in the universe bend and distort light due to the force of their gravity. The phenomenon is called “gravitational lensing”. By studying how light is distorted by galaxy clusters, astronomers have been able to create a map of dark matter in the universe.

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-    Several astronomical measurements have corroborated the existence of dark matter, leading to a world-wide effort to observe directly dark matter particle interactions with ordinary matter in extremely sensitive detectors, which would confirm its existence and shed light on its properties.  However, these interactions are so feeble that they have escaped direct detection up to this point, forcing scientists to build detectors that are more and more sensitive.

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-    Despite all the evidence pointing towards the existence of dark matter, there is also the possibility that no such thing exists after all and that the laws of gravity describing the motion of objects within the solar system require revision.

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-    Dark matter appears to be spread across the universe in a net-like pattern, with galaxy clusters forming at the nodes where fibers intersect. By verifying that gravity acts the same both inside and outside our solar system, researchers provide additional evidence for the existence of dark matter.

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-     (Things are even more complicated as in addition to dark matter there also appears to be “dark energy”, an invisible force responsible for the expansion of the universe that acts against gravity.)

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-    Dark matter might be concentrated in black holes, the powerful gates to nothing that due to the extreme force of their gravity devour everything in their vicinity. As such, dark matter would have been created in the Big Bang together with all other constituting elements of the universe as we see it today.

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-    Stellar remnants such as white dwarfs and neutron stars are also thought to contain high amounts of dark matter, and so are the “brown dwarfs”, failed stars that didn't accumulate enough material to kick-start nuclear fusion in their cores.

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-   Since we can't see dark matter, can we actually study it? There are two approaches to learning more about this mysterious stuff. Astronomers study the distribution of dark matter in the universe by looking at the clustering of material and the motion of objects in the universe. Particle physicists, on the other hand, are on a quest to detect the fundamental particles making up dark matter.

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-    An experiment mounted on the International Space Station called the “Alpha Magnetic Spectrometer” (AMS) detects antimatter in cosmic rays. Since 2011, it has been hit by more than 100 billion cosmic rays, providing fascinating insights into the composition of particles traversing the universe.

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-    We have measured an excess of “positrons” [the antimatter counterpart to an electron], and this excess can come from dark matter. 

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-   Back on Earth, beneath a mountain in Italy, the “LNGS's XENON1T” is hunting for signs of interactions after WIMPs collide with xenon atoms.    The “Large Underground Xenon dark-matter” experiment (LUX), seated in a gold mine in South Dakota, has also been hunting for signs of WIMP and xenon interactions. But so far, the instrument hasn't revealed the mysterious matter.

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-    The IceCube Neutrino Observatory, an experiment buried under the frozen surface of Antarctica, is hunting for the hypothetical sterile neutrinos. Sterile neutrinos only interact with regular matter through gravity, making it a strong candidate for dark matter.

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-    Experiments aiming to detect elusive dark matter particles are also conducted in the powerful particle colliders at the European Organization for Nuclear Research (CERN) in Switzerland.

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-    Several telescopes orbiting Earth are hunting for the effects of dark matter. The European Space Agency's Planck spacecraft, retired in 2013, spent four years in the Lagrangian Point 2 (a point in the orbit around the sun, where a spacecraft maintains a stable position with respect to Earth), mapping the distribution of the cosmic microwave background, a relic from the Big Bang, in the universe. Irregularities in the distribution of this microwave background revealed “clues” about the distribution of dark matter.

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-   In 2014, NASA's Fermi Gamma-ray Space Telescope made maps of the heart of our galaxy, the Milky Way, in gamma-ray light, revealing an excess of gamma-ray emissions extending from its core.

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-    The signal found cannot be explained by currently proposed alternatives and is in close agreement with the predictions of very simple dark matter models.   The excess can be explained by annihilations of dark matter particles with a mass between 31 and 40 billion electron volts.

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-   The James Webb Space Telescope, launched after 30 years of development on December 25, 2021, is also expected to contribute to the hunt for the elusive substance. With its infrared eyes able to see to the beginning of time, the telescope of the century won't be able to see dark matter directly, but through observing the evolution of galaxies since the earliest stages of the universe, it is expected to provide insights that have not been possible before. 

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-   ESA's Euclid mission launched on July 1, 2023, and is currently on the hunt for dark matter and dark energy. The mission aims to map the geometry of matter in the universe, specifically the distribution of galaxies to learn more about the elusive dark matter

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-    The “DAMA/LIBRA” experiment at the Gran Sasso National Laboratory (LNGS) near L’Aquila, Italy, has been recording an annual fluctuation of light flashes in its detector that appears to be a sign of dark matter. But no one has been able to definitively replicate the findings.

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-   But beneath a mountain in Jeongseon, South Korea, researchers are scaling up an experiment that could finally lay the controversial dark-matter claim to rest. In June, researchers will finish installing a revamped detector in a brand-new facility called “Yemilab”. If all goes to plan, the upgraded “COSINE-100” experiment will be running by August, 2024.

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-    DAMA/LIBRA’s observations of the distinct annual pattern is consistent with what physicists would expect with Earth’s relative position in the galaxy throughout the year. As the Earth orbits the Sun, the Sun orbits the black hole at the center of the Milky Way.

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-     In June, the Earth hurtles through the Milky Way in the same direction as the Sun, increasing its relative speed through the haze of dark matter. But in December, the Earth travels with the flow of dark matter as it moves in the opposite direction to the Sun. As expected, the number of signals recorded by DAMA/LIBRA’s detector are highest in June and lowest in December.

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-    Yemilab also offers a better-shielded environment for detecting elusive particles besides dark matter. The facility will also hunt for “neutrinos”,  chargeless particles that barely have mass. The second phase of an experiment called “AMoRE” will search for signs of two neutrons decaying into protons and electrons without emitting a neutrino.

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-    This hypothesized process is called “neutrinoless double β decay” and if observed, it will demonstrate that neutrinos are their own antiparticle. This could offer clues about their mass and explain why there is more matter than antimatter in the Universe.

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-    The upgraded neutrino detector will use around 160 kilograms of crystals embedded with molybdenum-100, a naturally occurring radioisotope. When “AMoRE-II” starts running at the end of this year,2024, it will be 100 times more sensitive than the previous version of the experiment.

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-   Whether the two experiments succeed or fail at detecting the rare events they are looking for, they are nevertheless set to raise more questions.   If both will deliver only null results, we should seriously start rethinking the Universe.

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June 11, 2024                     DARK  MATTER  -  what is it?                      4498

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