Simulating Direct-Collapse Black Holes: Gravitational Waveform Predictions for LISA
ORAL
Abstract
Investigating direct-collapse black hole (DCBH) formation is crucial for understanding the massive black hole population in the early universe. DCBHs could be important gravitational wave sources for the Laser Interferometer Space Antenna (LISA), but only a few numerical waveforms and crude analytical estimates exist, reflecting our limited theoretical understanding of these systems. Increasing the number and accuracy of waveform predictions is essential to maximize the scientific output of future LISA detections.
We present a pipeline to study DCBH formation: starting with a collapsing region from a cosmological simulation, we perform a stellar evolution, followed by modeling black hole formation and gravitational wave signals using numerical relativity. We focus on the techniques and tools required at the final stage of this pipeline. These simulations will enable us to assess and improve LISA's detection and identification capabilities for these events.
We present a pipeline to study DCBH formation: starting with a collapsing region from a cosmological simulation, we perform a stellar evolution, followed by modeling black hole formation and gravitational wave signals using numerical relativity. We focus on the techniques and tools required at the final stage of this pipeline. These simulations will enable us to assess and improve LISA's detection and identification capabilities for these events.
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Presenters
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Leonardo Werneck
University of Idaho
Authors
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Leonardo Werneck
University of Idaho
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Bernard J Kelly
University of Maryland Baltimore County
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Sarah Gossan
Hofstra University
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Zach B Etienne
University of Idaho, U Idaho
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John G Baker
NASA Goddard Space Flight Center
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John Wise
Georgia Institute of Technology
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Aláine Lee
NASA Goddard Space Flight Center
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Dominique Powell
Hofstra University
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Jackson Thomas
Hofstra University
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Thiago Assumpcao
West Virginia University