Neutron Star Mountains Would Cause Ripples in Space-Time
Extreme stars may have mountains like those on moons in our solar system. If so, they could produce detectable oscillations of space and time.
The Science
Collapsed dead stars, known as neutron stars, are a trillion times denser than lead, and their surface features are largely unknown. Nuclear theorists explored mountain building mechanisms active on the moons and planets in our solar system. Some of these mechanisms suggest that neutron stars are likely to have mountains. Neutron star mountains would be much more massive than any on Earth--so massive that gravity just from these mountains could produce small oscillations, or ripples, in the fabric of space and time. The Laser Interferometer Gravitational Wave Observatory (LIGO) is now searching for the ripples these mountains would make.
The Impact
This research on how to look for neutron star mountains will guide searches for oscillations of space-time known as continuous gravitational waves. These waves are so weak that they can only be detected with very detailed and sensitive searches that are carefully tuned to predicted frequencies and other signal properties. The first detections of continuous gravitational waves will open a new window on the universe and provide unique information on neutron stars, the densest objects short of black holes. These signals may also provide sensitive tests of the fundamental laws of nature.
Summary
Mountains or non-axisymmetric deformations of rotating neutron stars efficiently radiate gravitational waves. Nuclear theorists at Indiana University considered analogies between neutron star mountains and surface features of solar system bodies. Both neutron stars and certain moons such as Jupiter’s moon Europa or Saturn’s moon Enceladus have thin crusts over deep oceans, while Mercury has a thin crust over a large metallic core. Thin sheets may wrinkle in universal ways. Europa has linear features, Enceladus has tiger-like stripes, and Mercury has curved, step-like structures.
Neutron stars with mountains may have analogous types of surface features that could be discovered by observing continuous gravitational wave signals. The innermost inner core of the Earth is anisotropic with a shear modulus that depends on direction. If neutron star crust material is also anisotropic, a mountain-like deformation will result, and its height will increase as the star spins faster. Such a surface feature could explain the maximum spin observed for neutron stars and a possible minimum deformation of radio-emitting neutron stars known as millisecond pulsars.
Contact
Charles J. HorowitzIndiana University
horowit@iu.edu
Funding
This research was primarily funded by the Department of Energy Office of Science, Nuclear Physics program. Additional funding was provided by the National Science Foundation.
Publications
Morales, A. and Horowitz, C. J., Anisotropic neutron star crust, solar system mountains and gravitational waves, Physical Review D 110, 044016 (2024).
Highlight Categories
Program: NP
Performer: University