TAPIR Seminar
My main interests are in the intersection of relativistic physics and low-level coding. Naturally, for my PhD research I am working on numerical simulations of binary black hole systems in the intermediate mass-ratio region. This primarily involves contributing to the Spectre code by the SXS collaboration. My PhD supervisor is Prof. Dr. Harald Pfeiffer.
In person: 370 Cahill -- Attendees joining in person must have a valid Caltech UID.
To Join via Zoom: 864 8902 5566
ABSTRACT: Binary black hole simulations become increasingly more computationally expensive with smaller mass ratios, partly because of the longer evolution time, and partly because the lengthscale disparity dictates smaller time steps. The program initiated by Dhesi et al. [Phys. Rev D 104, 124002 (2021)] explores a method for alleviating the scale disparity in simulations with mass ratios in the intermediate astrophysical range (10^−4 < 𝑞 < 10^−2 ), where purely perturbative methods may not be adequate. A region ("worldtube") much larger than the small black hole is excised from the numerical domain, and replaced with an analytical model approximating a tidally deformed black hole. Here we apply this idea to a toy model of a scalar charge in a fixed circular geodesic orbit around a Schwarzschild black hole, solving for the massless Klein-Gordon field. This is a first implementation of the worldtube excision method in full 3+1 dimensions. We demonstrate the accuracy and efficiency of the method, and discuss the steps towards applying it for evolving orbits and, ultimately, in the binary black-hole scenario. Our implementation is publicly accessible in the SpECTRE numerical relativity code.