We live in a fortuitous time when it comes to gravitational-wave astronomy. Since the
inaugural detection of the black-hole binary GW150914 (Abbott et al., 2016), sensitive …

Gravitational-wave astronomy is a new field of discovery. With the first direct observation of
gravitational waves from merging black holes in 2015, this field has expanded significantly …

The landmark detection of gravitational waves (GWs) emitted by black-hole (BH) and
neutron-star (NS) binaries has opened a new era in physics, giving access to hitherto …

We discuss different ways that neutron stars can generate gravitational waves, describe
recent improvements in modelling the relevant scenarios in the context of improving detector …

In 2015, almost a century after Einstein published the general theory of relativity, one of its
most important predictions was verified by direct detection: the production of gravitational …

Recent gravitational-wave observations from the LIGO and Virgo observatories have
brought a sense of great excitement to scientists and citizens the world over. Since …

The detection of GW170817, the first neutron star-neutron star merger observed by
Advanced LIGO and Virgo, and its following analyses represent the first contributions of …

The first direct detection of gravitational waves emitted from a pair of merging black holes in
2015 has been heralded as one of most significant scientific breakthroughs in physics and …

The observation of gravitational wave signals from binary black hole mergers has
established the field of gravitational wave astronomy. It is expected that future networks of …

Neutron stars are one of the most mysterious wonders in the Universe. Their extreme
densities hint at new and exotic physics at work within. Gravitational waves could be the key …