With the remarkable advent of gravitational-wave astronomy, we have shed light on previously shrouded events: compact binary coalescences. Neutron stars are promising (and confirmed) sources of gravitational radiation and it proves timely to consider the ways in which these stars can be deformed. Gravitational waves provide a unique window through which to examine neutron-star interiors and learn more about the equation of state of ultra-dense nuclear matter. In this work, we study two relevant scenarios forgravitational-wave emission: neutron stars that host (non-axially symmetric) mountains and neutron stars deformed by the tidal field of a binary partner. Although they have yet to be seen with gravitational waves, rotating neutron stars ...
In this review we examine the dynamics and gravitational wave detectability of rotating strained neu...
A strong candidate for a source of gravitational waves is a highly magnetized, rapidly rotat-ing neu...
The gravitational waves that bathe the Earth presumably do not vary wildly in strength from year to ...
This thesis is devoted to studying gravitational waves from “mountains” on neutron stars. It is, in...
As the era of gravitational-wave astronomy has well and truly begun, gravitational radiation from ro...
Rapidly spinning, deformed neutron stars have long been considered potential gravitational-wave emit...
With the detection of GW150914, the era of gravitational wave astronomy has commenced. One possible ...
Fast rotating isolated neutron stars are strong sources of gravitational waves when deformed. One p...
The aim of this work is to compare a neutron star with an accreted crust and one with a non-accreted...
Neutron stars are known to contain extremely powerful magnetic fields. Their effect is to deform the...
We discuss the response of neutron stars to the tidal interaction in a compact binary system, as enc...
International audienceGravitational waves from neutron-star mergers are expected to provide stringen...
Many different astrophysical events related to pulsars are taught to be due to starquakes, that coul...
This work is the first in a series of studies aimed at understanding the dynamics of highly eccentri...
After the first direct observations of gravitational waves generated by the coalescence of binary bl...
In this review we examine the dynamics and gravitational wave detectability of rotating strained neu...
A strong candidate for a source of gravitational waves is a highly magnetized, rapidly rotat-ing neu...
The gravitational waves that bathe the Earth presumably do not vary wildly in strength from year to ...
This thesis is devoted to studying gravitational waves from “mountains” on neutron stars. It is, in...
As the era of gravitational-wave astronomy has well and truly begun, gravitational radiation from ro...
Rapidly spinning, deformed neutron stars have long been considered potential gravitational-wave emit...
With the detection of GW150914, the era of gravitational wave astronomy has commenced. One possible ...
Fast rotating isolated neutron stars are strong sources of gravitational waves when deformed. One p...
The aim of this work is to compare a neutron star with an accreted crust and one with a non-accreted...
Neutron stars are known to contain extremely powerful magnetic fields. Their effect is to deform the...
We discuss the response of neutron stars to the tidal interaction in a compact binary system, as enc...
International audienceGravitational waves from neutron-star mergers are expected to provide stringen...
Many different astrophysical events related to pulsars are taught to be due to starquakes, that coul...
This work is the first in a series of studies aimed at understanding the dynamics of highly eccentri...
After the first direct observations of gravitational waves generated by the coalescence of binary bl...
In this review we examine the dynamics and gravitational wave detectability of rotating strained neu...
A strong candidate for a source of gravitational waves is a highly magnetized, rapidly rotat-ing neu...
The gravitational waves that bathe the Earth presumably do not vary wildly in strength from year to ...