Did this newfound particle form the universe's dark matter?

A ghostly ring of dark matter floating in the galaxy cluster ZwCl0024+1652, one of the strongest pieces of evidence to date for the existence of dark matter. Astronomers think the dark-matter ring was produced from a collision between two gigantic clusters.
A ghostly ring of dark matter floating in the galaxy cluster ZwCl0024+1652, one of the strongest pieces of evidence to date for the existence of dark matter. Astronomers think the dark-matter ring was produced from a collision between two gigantic clusters. (Image credit: ESA/Hubble)

Researchers think that a newly identified subatomic particle may have formed the universe's dark matter right after the Big Bang, approximately 13.8 billion years ago. 

While scientists have determined that up to 27% of the matter in the universe could be dark matter, our understanding of what the mysterious substance might be is still lacking, as no one has ever directly observed it. 

Now, in a new study, nuclear physicists have suggested that dark matter could be made from a newly identified particle: the d-star hexaquark.

Related: The 11 Biggest unanswered questions about dark matter

What's a hexaquark?

Matter can be broken down into molecules, which can be broken down further into atoms and even further into the subatomic particles protons and neutrons. Then, when you break those down, you get quarks. So, everything we've ever seen, touched or tasted has ultimately been made up of quarks.

While neutrons and protons are each made up of three quarks, hexaquarks are made up of six. Their existence was predicted for decades, and in 2014, researchers were able to confirm the existence of hexaquarks

Though these exotic particles are made up of more quarks than protons are, hexaquarks are actually much smaller than the more familiar particles. Hexaquarks also decay much faster than other subatomic particles. Hexaquarks are also a type of boson particle, meaning that multiple d-star hexaquarks can combine in ways different from how protons and neutrons combine. 

So, how can these teeny, tiny hexaquarks be the key to understanding dark matter?

As Mikhail, Bashkanov, a researcher from the department of physics at the University of York in the United Kingdom, told Space.com, hexaquarks could have condensed into dark matter in the strange conditions directly after the Big Bang. 

Hexaquarks, condensed

Immediately following that event, the universe was a cooling sea of subatomic particles, "a big pot of soup with quarks," Bashkanov said. 

Bashkanov and co-author, University of York professor Daniel Watts, said in this new study that, during this super early period of the universe, d-star hexaquarks could have cooled and expanded into what is known as a Bose-Einstein condensate (BEC). 

A BEC is an exotic, fifth state of matter that forms when a cloud of atoms or subatomic particles cools to temperatures approaching absolute zero, or 0 Kelvin (minus 459.67 degrees Fahrenheit, or minus 273.15 degrees Celsius). At these extreme temperatures, the particles (or atoms) clump together into a single entity that can be described by a wave function. In other words, the particles coalesce and behave like a single particle (or atom). 

While hexaquarks decay quickly in a lab, Bashkanov explained that they are much more stable and long-lasting within a neutron star and, the researchers think, possibly also in a BEC. 

So, as Bashkanov explained, the scientists think that, shortly after the universe began with the Big Bang, hexaquarks could have condensed into a BEC — and that unique BEC could be dark matter.

"Our first calculations indicate that condensates of d-stars are a feasible new candidate for dark matter, and this new possibility seems worthy of further, more detailed investigation," Watts said in a statement. "The result is particularly exciting since it doesn't require any concepts that are new to physics."

This early work hasn't solved the dark matter question for good. But Watts and Bashkanov plan to continue studying hexaquarks to better understand the strange particles and further explore whether they really could be good candidates for dark matter. 

As Bashkanov explained, the researchers going forward will perform experiments to study the properties of hexaquarks, like their size and how they interact with both other hexaquarks and normal, or nuclear matter (protons and neutrons inside a nucleus). While the researchers said (as they explored in this paper) that hexaquarks could condense into a BEC, they hope to show that this is true through further study and experimentation. 

This work was published Feb. 12 in the Journal of Physics G Letters.

Editor's Note: A correction was made to show that the universe is likely made up of 27 percent dark matter and that hexaquarks are bosons. 

Follow Chelsea Gohd on Twitter @chelsea_gohd. Follow us on Twitter @Spacedotcom and on Facebook.

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Chelsea Gohd
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Chelsea “Foxanne” Gohd joined Space.com in 2018 and is now a Senior Writer, writing about everything from climate change to planetary science and human spaceflight in both articles and on-camera in videos. With a degree in Public Health and biological sciences, Chelsea has written and worked for institutions including the American Museum of Natural History, Scientific American, Discover Magazine Blog, Astronomy Magazine and Live Science. When not writing, editing or filming something space-y, Chelsea "Foxanne" Gohd is writing music and performing as Foxanne, even launching a song to space in 2021 with Inspiration4. You can follow her on Twitter @chelsea_gohd and @foxannemusic.

  • rod
    Admin said:
    Researchers think that a newly identified subatomic particle may have formed the universe's dark matter right after the Big Bang, approximately 13.8 billion years ago.

    Did this newfound particle form the universe's dark matter? : Read more

    This report appears to have some experimental means of verification. "Now, in a new study, nuclear physicists have suggested that dark matter could be made from a newly identified particle: the d-star hexaquark....This early work hasn't solved the dark matter question for good. But Watts and Bashkanov plan to continue studying hexaquarks to better understand the strange particles and further explore whether they really could be good candidates for dark matter. As Bashkanov explained, the researchers going forward will perform experiments to study the properties of hexaquarks, like their size and how they interact with both other hexaquarks and normal, or nuclear matter (protons and neutrons inside a nucleus). While the researchers said (as they explored in this paper) that hexaquarks could condense into a BEC, they hope to show that this is true through further study and experimentation."

    Recently axions were proposed as a dark matter solution too, https://www.livescience.com/axion-found-in-weyl-semimetal.html

    The search continues now with the d-star hexaquark, "Despite many decades of study the physical origin of "dark matter" in the Universe remains elusive. In this letter we calculate the properties of a completely new dark matter candidate - Bose-Einstein condensates formed from a recently discovered bosonic particle in the light-quark sector, the d∗(2380) hexaquark. In this first study, we show stable d∗(2380) Bose-Einstein condensates could form in the primordial early universe, with a production rate sufficiently large that they are a plausible new candidate for dark matter. Some possible astronomical signatures of such dark matter are also presented. ", ref https://arxiv.org/abs/2001.08654
    WIMPS are proposed too, https://phys.org/news/2013-02-scientists-breakthroughs-dark-matter-mystery.html There are some important observations supporting dark matter in astronomy, this report said "The dark matter theory was born 80 years ago when Swiss astrophysicist Fritz Zwicky discovered that there was not enough mass in observable stars or galaxies to allow the force of gravity to hold them together."

    Holding spiral galaxies together is critical for the long time scales used in the Big Bang model of origins.
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