Formulas for GW damping and heating effects are derived for arbitrary ℓ ≥ 2, with enhanced effects suggesting higher modes are unlikely to be observed in astrophysical GW signals.
Linearized solutions of the Einstein equations within a Bondi-Sachs framework, and implications for boundary conditions in numerical simulations
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abstract
We linearize the Einstein equations when the metric is Bondi-Sachs, when the background is Schwarzschild or Minkowski, and when there is a matter source in the form of a thin shell whose density varies with time and angular position. By performing an eigenfunction decomposition, we reduce the problem to a system of linear ordinary differential equations which we are able to solve. The solutions are relevant to the characteristic formulation of numerical relativity: (a) as exact solutions against which computations of gravitational radiation can be compared; and (b) in formulating boundary conditions on the $r=2M$ Schwarzschild horizon.
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gr-qc 1years
2026 1verdicts
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Gravitational wave interactions with matter: beyond quadrupolar perturbations
Formulas for GW damping and heating effects are derived for arbitrary ℓ ≥ 2, with enhanced effects suggesting higher modes are unlikely to be observed in astrophysical GW signals.