This review paper explores the advancements in numerical relativity (NR) simulations, focusing on resolving gravitational memory effects and implementing BMS frame fixing.
The paper begins by explaining the importance of testing Einstein's theory of general relativity (GR) using gravitational waves (GWs) generated by binary black hole mergers. It highlights the significance of numerical relativity in producing accurate GW templates for these tests. The authors then introduce memory effects, a subtle but detectable prediction of GR, where the spacetime permanently changes after the passage of GWs. These effects are linked to the BMS group, a symmetry group of asymptotically flat spacetimes that extends the Poincaré group of special relativity.
The paper provides a pedagogical introduction to the BMS group, emphasizing the concept of supertranslations. Supertranslations are angle-dependent shifts in the retarded time coordinate, representing the residual gauge freedom at future null infinity (I+). The authors explain how supertranslations arise from the causal disconnection of observers at I+ and how they, along with Lorentz transformations, constitute the BMS group. The paper then elucidates how BMS transformations affect the asymptotic data at I+, including the gravitational wave strain and Weyl scalars.
The paper connects memory effects to conservation laws arising from the BMS symmetries. It explains how supertranslations lead to a balance law between the change in the angle-dependent mass and the flux of angle-dependent energy, ultimately manifesting as a net change in the gravitational wave strain. The authors differentiate between ordinary memory, sourced by unbound masses, and null memory, sourced by the energy flux of radiation.
The paper reviews the computational methods used to simulate GWs at I+, highlighting the Cauchy-characteristic evolution (CCE) technique. It discusses the challenges of comparing NR waveforms containing memory to post-Newtonian waveforms and introduces the BMS frame fixing program as a solution. This program aims to fix the coordinate freedom in NR waveforms, enabling accurate comparisons and hybrid modeling with other waveform models.
The review concludes by emphasizing the importance of BMS frame fixing for improving the accuracy and robustness of GW models. It highlights the potential of these advancements for observing new physics, testing GR, and gaining deeper insights into the universe's astrophysical properties.
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