Saketh, M.V.S., & Maggio, E. (2024). Quasinormal modes of slowly-spinning horizonless compact objects. arXiv preprint arXiv:2406.10070v3.
This paper investigates the quasinormal mode (QNM) spectrum of slowly-spinning horizonless compact objects (HCOs) as a means to distinguish them from black holes. The authors aim to understand the relationship between QNMs, object reflectivity, and the parameters of the membrane paradigm, a framework used to model HCOs.
The authors extend the membrane paradigm to incorporate spin effects to the linear order. They derive boundary conditions for metric perturbations at the membrane surface using the Israel-Darmois junction conditions. These boundary conditions, along with the Regge-Wheeler and Zerilli equations governing perturbations, are used to numerically compute the reflectivity and QNM frequencies of HCOs.
The study demonstrates that the membrane paradigm, extended to include spin, provides a valuable framework for analyzing the QNM spectrum of HCOs. The findings suggest that the spin of these objects plays a crucial role in their detectability through gravitational wave observations, particularly during the ringdown phase.
This research contributes to the ongoing effort to understand the nature of compact objects and test the predictions of general relativity. The ability to distinguish HCOs from black holes through their QNM spectrum has significant implications for gravitational wave astronomy and our understanding of gravity in the strong-field regime.
The study focuses on the linear-in-spin approximation, which limits its applicability to slowly rotating objects. Future research could extend the analysis to higher orders in spin to capture a wider range of astrophysical scenarios. Additionally, exploring specific models of HCOs and their corresponding membrane parameters would provide more concrete predictions for gravitational wave observations.
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