麻豆淫院

One of the most high-profile mysteries in physics today is what scientists refer to as the "Strong CP Problem." Stemming from the puzzling phenomenon that neutrons do not interact with electric fields despite being made up of quarks鈥攕maller, fundamental particles that carry electric charges鈥攖he Strong CP Problem puts into question the Standard Model of physics, or the set of theories scientists have been using to explain the laws of nature for years.

A team led by University of Minnesota Twin Cities theoretical physicists has discovered a new way to search for axions, hypothetical particles that could help solve this mystery. Working in collaboration with experimental researchers at the Fermilab National Accelerator Laboratory, the physicists' new strategy opens up previously unexplored opportunities to detect axions in particle collider experiments.

The researchers' paper is published and featured as the Editor's suggestion in 麻豆淫院ical Review Letters.

"As particle physicists, we're trying to develop our best understanding of nature," said Zhen Liu, co-author of the paper and an assistant professor in the University of Minnesota School of 麻豆淫院ics and Astronomy. "Scientists have been tremendously successful in the past century in finding elementary particles through established theoretical frameworks. So, it's extremely puzzling why neutrons do not couple to electric fields because in our known theory, we would expect them to. If we do discover the axion, it will be a great advance in our fundamental understanding of the structure of nature."

One of the primary means for studying subatomic particles, and potentially discovering new ones, is collider experiments. Essentially, scientists force beams of particles to collide鈥攁nd when they hit each other, the energy they produce creates other particles that pass through a detector, allowing researchers to analyze their properties.

Liu and his team's proposed method involves measuring the "decay" product鈥攐r what happens when an unstable heavy particle transforms into multiple lighter particles鈥攐f the hypothetical axion into two muons鈥攌nown particles that are essentially the heavier version of the electron. By working backward from the muon tracks in the detector to reconstruct such decays, the researchers believe they have a chance to locate the axion and prove its existence.

"With this research, we're expanding ways we can search for the axion particle," said Raymond Co, co-author of the paper and a postdoctoral researcher in the University of Minnesota School of 麻豆淫院ics and Astronomy and William Fine Theoretical 麻豆淫院ics Institute. "People have never used axion decay into muons as a way to search for the axion particle in neutrino or collider experiments before. This research opens up new possibilities to pave the way for future endeavors in our field."

Liu and Co, along with University of Minnesota physics and astronomy postdoctoral researcher Kun-Feng Lyu and University of California, Berkeley postdoctoral researcher Soubhik Kumar, are behind the theoretical part of the research. They're a part of the ArgoNeuT collaboration, which brings together theorists and experimentalists from across the country to study particles through experiments at Fermilab.

In this paper, the University of Minnesota-led theoretical team worked with the experimental researchers to perform a search for axions using their new method and existing data from the ArgoNeuT experiment. The researchers plan to use the experimental results to further refine their theoretical calculations of the axion production rate in the future.