Physicists are closer than
ever to answering fundamental questions about the origins of the universe by
learning more about its tiniest particles.
University of Cincinnati Professor
Alexandre Sousa in a new paper outlined the next 10 years of global research
into the behavior of neutrinos, particles so tiny that they pass through
virtually everything by the trillions every second at nearly the speed of
light.
Neutrinos are the most abundant
particles with mass in the universe, so scientists want to know more about
them.
They are created by nuclear fusion
reactions in the sun, radioactive decay in nuclear reactors or the Earth’s
crust or in particle accelerator labs. As they travel, they can transition
between one of three types or “flavors” of neutrinos and back.
But unexpected experimental results made
physicists suspect there might be another neutrino flavor, called a sterile
neutrino because it appears immune to three of the four known “forces.”
“Theoretically, it interacts with
gravity, but it has no interaction with the others, weak nuclear force, strong
nuclear force or electromagnetic force,” Sousa said.
In a new white paper published in the Journal of Physics G, Sousa and his co-authors discuss experimental
anomalies in neutrino exploration that have baffled researchers.
The paper was a product of the
Particle Physics Community Planning Exercise, referred to as “Snowmass
2021/2022.“
Representatives in high energy physics
gather every 10 years to collaborate on the future of particle physics in the
United States and its international partners.
Their collective vision is articulated
and confronted with science funding scenarios by the Particle Physics Project
Prioritization Panel, or P5, whose final report issued in 2023 made direct
recommendations to Congress about funding the projects.
Sousa was a corresponding author of the
paper that discusses some of the most promising projects coming in the next
decade.
UC Professor Jure Zupan, UC Associate
Professor Adam Aurisano, UC visiting scholar Tarak Thakore, UC postdoctoral
fellow Michael Wallbank and UC physics students Herilala Razafinime and Miriama
Rajaoalisoa also contributed to the paper.
“Progress in neutrino physics is
expected on several fronts,” Zupan said.
Besides the search for sterile
neutrinos, Zupan said physicists are looking at several experimental anomalies
— disagreements between data and theory — that they will be able to test in the
near future with the upcoming experiments.
Learning more about neutrinos could
upend centuries of our understanding about physics. Several neutrino projects
have been recognized with the world’s top scientific award, the Nobel Prize,
most recently with the discovery of neutrino oscillations receiving the 2015
Nobel Prize in Physics. Countries such as the United States are investing
billions of dollars into these projects because of the immense scientific
interest in pursuing these questions.
One question is why the universe has
more matter than antimatter if the Big Bang created both in equal measure.
Neutrino research could provide the answer, Sousa said.
“It might not make a difference in your
daily life, but we’re trying to understand why we’re here,” Sousa said.
“Neutrinos seem to hold the key to answering these very deep questions.”
Sousa is part of one of the most
ambitious neutrino projects called DUNE or the Deep Underground Neutrino
Experiment conducted by the Fermi National Accelerator Laboratory. Crews have
excavated the former Homestake gold mine 5,000 feet underground to install
neutrino detectors. It takes about 10 minutes just for the elevator to reach
the detector caverns, Sousa said.
Researchers put detectors deep
underground to shield them from cosmic rays and background radiation. This
makes it easier to isolate the particles generated in experiments.
The experiment is set to begin in 2029
with two of its detector modules measuring neutrinos from the atmosphere. But
starting in 2031, researchers at Fermilab will shoot a high-energy beam of
neutrinos 800 miles through the Earth to the waiting detector in South Dakota
and a much closer one in Illinois. The project is a collaboration of more than
1,400 international engineers, physicists and other scientists.
“With these two detector modules and the
most powerful neutrino beam ever we can do a lot of science,” Sousa said. “DUNE
coming online will be extremely exciting. It will be the best neutrino
experiment ever.”
The paper was an ambitious undertaking,
featuring more than 170 contributors from 118 universities or institutes and 14
editors, including Sousa.
“It was a very good example of
collaboration with a diverse group of scientists. It’s not always easy, but
it’s a pleasure when it comes together,” he said.
Meanwhile, Sousa and UC’s Aurisano are
also involved in another Fermilab neutrino experiment called NOvA that examines
how and why neutrinos change flavor and back. In June, his research group
reported on their latest findings, providing the most precise measurements of
neutrino mass to date.
Another major project called
Hyper-Kamiokande, or Hyper-K, is a neutrino observatory and experiment under
construction in Japan. Operations there could begin as early as 2027 as it,
too, looks for evidence of sterile neutrinos, among other research questions.
“That should hold very interesting
results, especially when you put them together with DUNE. So the two
experiments combined will advance our knowledge immensely,” Sousa said. “We should have
some answers during the 2030s.”
UC’s Zupan said these
multibillion-dollar projects hold promise for answering core questions about
matter and antimatter and the origins of the universe.
“So far we know of only one such
parameter in particle physics that has a nonzero value, and has to do with the
properties of quarks,” Zupan said. Whether or not something similar also is
present for the neutrinos is an interesting open question.”
Sousa said scientists around the world
are working on many other neutrino experiments that could provide answers or
generate new questions.
And then?
“Then I’ll be thinking about
retirement,” Sousa joked.
Source: Particle research gets closer to answering why we’re here – Scents of Science
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