Dr Katy Clough

Superradiance in massive vector fields with spatially varying mass

ArXiv 2201.08305 (2022)

Authors:

Zipeng Wang, Thomas Helfer, Katy Clough, Emanuele Berti

GRChombo: An adaptable numerical relativity code for fundamental physics

(2022)

Authors:

Tomas Andrade, Llibert Areste Salo, Josu C Aurrekoetxea, Jamie Bamber, Katy Clough, Robin Croft, Eloy de Jong, Amelia Drew, Alejandro Duran, Pedro G Ferreira, Pau Figueras, Hal Finkel, Tiago França, Bo-Xuan Ge, Chenxia Gu, Thomas Helfer, Juha Jäykkä, Cristian Joana, Markus Kunesch, Kacper Kornet, Eugene A Lim, Francesco Muia, Zainab Nazari, Miren Radia, Justin Ripley, Paul Shellard, Ulrich Sperhake, Dina Traykova, Saran Tunyasuvunakool, Zipeng Wang, James Y Widdicombe, Kaze Wong

Lessons for adaptive mesh refinement in numerical relativity

ArXiv 2112.10567 (2021)

Authors:

Miren Radia, Ulrich Sperhake, Amelia Drew, Katy Clough, Pau Figueras, Eugene A Lim, Justin L Ripley, Josu C Aurrekoetxea, Tiago França, Thomas Helfer

GRChombo: An adaptable numerical relativity code for fundamental physics

The Journal of Open Source Software The Open Journal 6:68 (2021) 3703

Authors:

Tomas Andrade, Llibert Salo, Josu Aurrekoetxea, Jamie Bamber, Katy Clough, Robin Croft, Eloy de Jong, Amelia Drew, Alejandro Duran, Pedro Ferreira, Pau Figueras, Hal Finkel, Tiago Frana, Bo-Xuan Ge, Chenxia Gu, Thomas Helfer, Juha Jäykkä, Cristian Joana, Markus Kunesch, Kacper Kornet, Eugene Lim, Francesco Muia, Zainab Nazari, Miren Radia, Justin Ripley, Paul Shellard, Ulrich Sperhake, Dina Traykova, Saran Tunyasuvunakool, Zipeng Wang, James Widdicombe, Kaze Wong

Dynamical friction from scalar dark matter in the relativistic regime

Physical Review D American Physical Society 104:10 (2021) 103014

Authors:

Dina Traykova, Katherine Clough, Thomas Helfer, Emanuele Berti, Pedro G Ferreira, Lam Hui

Abstract:

Light bosonic scalars (e.g., axions) may form clouds around black holes via superradiant instabilities or via accretion if they form some component of the dark matter. It has been suggested that their presence may lead to a distinctive dephasing of the gravitational wave signal when a small compact object spirals into a larger black hole. Motivated by this, we study numerically the dynamical friction force on a black hole moving at relativistic velocities in a background scalar field with an asymptotically homogeneous energy density. We show that the relativistic scaling is analogous to that found for supersonic collisional fluids, assuming an approximate expression for the pressure correction which depends on the velocity and scalar mass. While we focus on a complex scalar field, our results confirm the expectation that real scalars would exert a force which oscillates between positive and negative values in time with a frequency set by the scalar mass. The complex field describes the time averaged value of this force, but in a real scalar, the rapid force oscillations could, in principle, leave an imprint on the trajectory. The approximation we obtain can be used to inform estimates of dephasing in the final stages of an extreme mass ratio inspiral.