TY - JOUR
T1 - A method for estimating time-frequency characteristics of compact binary mergers to improve searches for inspiral, merger and ring-down phases separately
AU - Hanna, Chad
AU - Megevand, Miguel
AU - Ochsner, Evan
AU - Palenzuela, Carlos
PY - 2009
Y1 - 2009
N2 - Recent advances in the description of compact binary systems have produced gravitational waveforms that include inspiral, merger and ring-down phases. Comparing results from numerical simulations with those of post-Newtonian, and related, expansions has provided motivation for employing post-Newtonian waveforms in near merger epochs when searching for gravitational waves and has encouraged the development of analytic fits to full numerical waveforms. Until searches employ full waveforms as templates, data analysts can still conduct separate inspiral, merger and ring-down searches. Improved knowledge about the end of the inspiral phase, the beginning of the merger and the ring-down frequencies will increase the efficiency of searches over each phase separately without needing the exact waveform. We will show that knowledge of the final spin, of which there are many theoretical models and analytic fits to simulations, may give an insight into the time-frequency properites of the merger. We also present implications on the ability to probe the tidal disruption of neutron stars through gravitational waves.
AB - Recent advances in the description of compact binary systems have produced gravitational waveforms that include inspiral, merger and ring-down phases. Comparing results from numerical simulations with those of post-Newtonian, and related, expansions has provided motivation for employing post-Newtonian waveforms in near merger epochs when searching for gravitational waves and has encouraged the development of analytic fits to full numerical waveforms. Until searches employ full waveforms as templates, data analysts can still conduct separate inspiral, merger and ring-down searches. Improved knowledge about the end of the inspiral phase, the beginning of the merger and the ring-down frequencies will increase the efficiency of searches over each phase separately without needing the exact waveform. We will show that knowledge of the final spin, of which there are many theoretical models and analytic fits to simulations, may give an insight into the time-frequency properites of the merger. We also present implications on the ability to probe the tidal disruption of neutron stars through gravitational waves.
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U2 - 10.1088/0264-9381/26/1/015009
DO - 10.1088/0264-9381/26/1/015009
M3 - Article
AN - SCOPUS:62649146439
SN - 0264-9381
VL - 26
JO - Classical and Quantum Gravity
JF - Classical and Quantum Gravity
IS - 1
M1 - 015009
ER -