Looking inside a neutron star — new model will improve insights gleaned from gravitational waves

Researchers at the University of Birmingham have demonstrated the way in which these vibrations, caused by the interactions between the two stars’ tidal fields as they get close together, affect gravitational-wave observations. The study is published in Physical Review Letters.

Taking these movements into account could make a huge difference to our understanding of the data taken by the Advanced LIGO and Virgo instruments, set up to detect gravitational waves — ripples in time and space — produced by the merging of black holes and neutron stars.

The researchers aim to have a new model ready for Advanced LIGO’s next observing run and even more advanced models for the next generation of Advanced LIGO instruments, called A+, which are due to begin their first observing run in 2025.

Since the first gravitational waves were detected by the LIGO Scientific Collaboration and Virgo Collaboration in 2016, scientists have been focused on advancing their understanding of the massive collisions that produce these signals, including the physics of a neutron star at supra nuclear densities.

Dr Geraint Pratten, of the Institute for Gravitational Wave Astronomy at University of Birmingham, is lead-author on the paper. He said: “Scientists are now able to get lots of crucial information about neutron stars from the latest gravitational wave detections. Details such as the relationship between the star’s mass and its radius, for example, provide crucial insight into fundamental physics behind neutron stars. If we neglect these additional effects, our understanding of the structure of the neutron star as a whole can become deeply biased.”

Dr Patricia Schmidt, co-author on the paper and Associate Professor at the Institute for Gravitational Wave Astronomy, added: “These refinements are really important. Within single neutron stars we can start to understand what’s happening deep inside the star’s core, where matter exists at temperatures and densities we cannot produce in ground-based experiments. At this point we might start to see atoms interacting with each other in ways we have not yet seen — potentially requiring new laws of physics.”

The refinements devised by the team represent the latest contribution from the University of Birmingham to the Advanced LIGO programme. Researchers in the University’s Institute for Gravitational Wave Astronomy have been deeply involved in design and development of the detectors since the programme’s earliest stages. Looking ahead, PhD student Natalie Williams is already progressing work on calculations to further refine and calibrate the new models.

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