Popis: |
Compact binary sources that emit gravitational waves (GW) are expected to be both spinning and have eccentric orbits. To date, there has been no closed-form expression for the phasing of GWs that contain information from both spin and eccentricity. The introduction of eccentricity can slow waveform generation, as obtaining closed-form expressions for the waveform phase is unattainable due to the complexity of the differential equations involved, often requiring slower numerical methods. However, closed-form expressions for the waveform phase can be obtained when eccentricity is treated as a small parameter, enabling quick waveform generation. In this paper, closed-form expressions for the GW phasing in the form of Taylor approximants up to the eighth power in initial eccentricity $(e_0)$ are obtained while also including aligned spins up to the third post-Newtonian order. The phasing is obtained in both time and frequency domains. The TaylorT2 phasing is also resummed for usage in scenarios where initial eccentricities are as high as 0.5. Finally, a waveform is constructed using the $e_{0}^2$ expanded TaylorF2 phasing for aligned-spin systems added to TaylorF2Ecc. We perform mismatch computation between this model and TaylorF2Ecc. The findings indicate that for eccentricities $\gtrsim 0.15$ (defined at 10 Hz) and small spins $(\sim 0.2 )$, the mismatches can be higher than 1%. This leads to an overall loss in signal-to-noise ratio and lower detection efficiency of GWs coming from eccentric spinning compact binary inspirals if the combined effects of eccentricity and aligned spins are neglected in the waveforms. |