By studying neutron 'starquakes', scientists aim to revolutionize nuclear matter research
by Sophie Jenkins
Bath UK (SPX) Feb 06, 2025

A new study led by the University of Bath suggests that investigating 'starquakes'-seismic activity in neutron stars-could unlock profound insights into the properties of nuclear matter. These findings have the potential to reshape current methodologies in nuclear physics and astronomy, with possible long-term applications in health, security, and energy.

The research, conducted by an international team of physicists including Dr. David Tsang and Dr. Duncan Neill from the Department of Physics at Bath, along with collaborators from Texas A and M and the University of Ohio, underscores the significance of asteroseismology-the study of stellar oscillations. Their study, published in Physical Review C, demonstrates how observing neutron star quakes can validate theories about nuclear matter.

Using powerful Earth-based telescopes to monitor these quakes, scientists gain critical insights into neutron star interiors. This approach helps assess the validity of Chiral Effective Field Theory, a framework essential for advancing nuclear physics and broadening our understanding of fundamental forces in the universe.

"Our findings promise to refine the tools used by nuclear physicists while bringing astronomy and nuclear physics into closer alignment," explained Dr. Neill, lead author and postdoctoral researcher. "These results emphasize how astronomical observations could significantly impact nuclear physics, bridging gaps between traditionally separate fields."

Advancing nuclear theory in this way could lead to benefits across multiple disciplines:

+ Health: Enhancing techniques in radiation therapy and medical imaging.

+ National Security: Contributing to the safe development and maintenance of nuclear weapons.

+ Nuclear Energy: Improving nuclear reactor designs and advancing future energy solutions.

The role of neutron stars in nuclear physics

Neutron stars, the ultra-dense remnants of massive stars, offer a natural laboratory for studying extreme states of matter. Their extreme conditions allow scientists to investigate nuclear matter properties beyond what is possible in terrestrial experiments.

Currently, one of the leading methods for modeling nuclear matter under extreme conditions is Chiral Effective Field Theory. However, for any theoretical framework to be robust, it must be tested against observable data.

Since neutron stars are incredibly distant, precise measurements are challenging, leading researchers to focus primarily on large-scale properties rather than intricate internal structures. This limitation has made it difficult to validate detailed theoretical predictions.

"We propose that asteroseismology could soon allow us to obtain highly detailed data on the internal composition of neutron stars, helping to refine theories like Chiral Effective Field Theory," said co-author Dr. David Tsang.

Dr. Neill added, "One advantage of our approach is that it leverages existing telescope technology, providing new applications for current observational instruments. This expands the toolkit of nuclear physics without necessitating costly new infrastructure.

"As this field progresses, asteroseismology could pinpoint the behavior of nuclear matter at various densities inside neutron stars, positioning astronomy as a key driver in refining nuclear physics techniques. We look forward to expanding our research efforts at Bath to explore the full potential of this approach."

The research team also included Dr. Christian Drischler from Ohio University and FRIB at Michigan State University, Dr. Jeremy Holt from Texas A and M University, College Station, and Dr. William Newton from Texas A and M University-Commerce.

Research Report:Resonant shattering flares as asteroseismic tests of chiral effective field theory

Related Links
Department of Physics at Bath
Stellar Chemistry, The Universe And All Within It