WDs and neutron stars are far-reaching and multi-faceted laboratories in the hunt for dark
matter. We review detection prospects of wave-like, particulate, macroscopic and black hole …

In this white paper, we discuss the prospects for characterizing and identifying dark matter
using gravitational waves, covering a wide range of dark matter candidate types and signals …

New Particles Beyond the Standard Model have always been thought to be charged under
at least some of the same gauge interactions of ordinary particles. Although this assumption …

The metastable hypermassive neutron star produced in the coalescence of two neutron stars
can copiously produce axions that radiatively decay into O (100) MeV photons. These …

Exploring dark matter via observations of extreme astrophysical environments--defined here
as heavy compact objects such as white dwarfs, neutron stars, and black holes, as well as …

A bstract In anticipation of upcoming gravitational wave experiments, we provide a
comprehensive overview of the spectra predicted by phase transitions triggered by states …

Light axion fields, if they exist, can be sourced by neutron stars due to their coupling to
nuclear matter, and play a role in binary neutron star mergers. We report on a search for …

A subfraction of dark matter or new particles trapped inside celestial objects can significantly
alter their macroscopic properties. We investigate the new physics imprint on celestial …

The neutron lifetime anomaly has been used to motivate the introduction of new physics with
hidden-sector particles coupled to baryon number, and on which neutron stars provide …

We show that gravitational wave emission from neutron star binaries can be used to
discover any generic long-ranged muonic force due to the large inevitable abundance of …