Neutron Star Deformations May Create Space-Time Ripples
by Clarence Oxford
Los Angeles CA (SPX) Jan 13, 2025

Collapsed stars, known as neutron stars, possess extraordinary density - a trillion times that of lead. Despite their significance, the surface features of neutron stars remain largely uncharted. Recent investigations by nuclear theorists have drawn parallels between mountain formation mechanisms on planetary bodies in our solar system and those on neutron stars. These findings suggest that neutron stars could host immense mountains, whose gravity could induce oscillations in the space-time continuum. The Laser Interferometer Gravitational Wave Observatory (LIGO) is actively searching for these subtle ripples, known as gravitational waves.

The Significance of This Research

The study of neutron star deformations lays a foundation for detecting continuous gravitational waves - persistent ripples in space-time. These waves are faint and require precise and sensitive detection methods calibrated to expected frequencies and signal characteristics. The ability to detect continuous gravitational waves will open a novel perspective on the universe, offering unique insights into neutron stars. As the densest objects next to black holes, neutron stars could reveal much about the fundamental laws of physics through these signals.

Connections to Solar System Geology

Rotating neutron stars with non-axisymmetric features efficiently emit gravitational waves. Researchers at Indiana University analyzed similarities between these features and geological patterns observed on celestial bodies within the solar system. For instance:

- Jupiter's moon Europa has linear surface features caused by its thin crust overlaying an ocean.

- Saturn's moon Enceladus displays tiger-like stripes.

- Mercury's surface showcases curved, step-like formations due to its crust over a metallic core.

These analogies suggest that neutron stars may exhibit similar surface deformations, which could be detected through gravitational wave analysis. Such features might arise from anisotropic properties of neutron star crust material, where directional dependence of shear modulus contributes to deformation. Faster star rotation could amplify these mountain-like structures, potentially explaining observed spin limits for neutron stars and deformations in millisecond pulsars.

Exploring Anisotropic Crusts and Gravitational Waves

The Earth's innermost core demonstrates anisotropy with direction-dependent shear properties, providing a comparative framework for neutron star crusts. If neutron star crusts are also anisotropic, their surface irregularities could become more pronounced with increasing spin rates. This characteristic might elucidate the maximum observed rotation speeds and minimal deformations in specific neutron stars. Observing these phenomena could bridge gaps in understanding stellar physics and refine gravitational wave detection models.

Research Report:Anisotropic neutron star crust, solar system mountains, and gravitational waves

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