Small mass plunging into a Kerr black hole: Anatomy of the inspiral-merger-ringdown waveforms
出版年份 2014 全文链接
标题
Small mass plunging into a Kerr black hole: Anatomy of the inspiral-merger-ringdown waveforms
作者
关键词
-
出版物
PHYSICAL REVIEW D
Volume 90, Issue 8, Pages -
出版商
American Physical Society (APS)
发表日期
2014-10-16
DOI
10.1103/physrevd.90.084025
参考文献
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注意:仅列出部分参考文献,下载原文获取全部文献信息。- Effective-one-body model for black-hole binaries with generic mass ratios and spins
- (2014) Andrea Taracchini et al. PHYSICAL REVIEW D
- Inspiral-merger-ringdown waveforms of spinning, precessing black-hole binaries in the effective-one-body formalism
- (2014) Yi Pan et al. PHYSICAL REVIEW D
- Error-analysis and comparison to analytical models of numerical waveforms produced by the NRAR Collaboration
- (2013) Ian Hinder et al. CLASSICAL AND QUANTUM GRAVITY
- Dynamical excision boundaries in spectral evolutions of binary black hole spacetimes
- (2013) Daniel A Hemberger et al. CLASSICAL AND QUANTUM GRAVITY
- Final spin and radiated energy in numerical simulations of binary black holes with equal masses and equal, aligned or antialigned spins
- (2013) Daniel A. Hemberger et al. PHYSICAL REVIEW D
- Decoding mode mixing in black-hole merger ringdown
- (2013) Bernard J. Kelly et al. PHYSICAL REVIEW D
- Improved effective-one-body description of coalescing nonspinning black-hole binaries and its numerical-relativity completion
- (2013) Thibault Damour et al. PHYSICAL REVIEW D
- Branching of quasinormal modes for nearly extremal Kerr black holes
- (2013) Huan Yang et al. PHYSICAL REVIEW D
- Modeling the horizon-absorbed gravitational flux for equatorial-circular orbits in Kerr spacetime
- (2013) Andrea Taracchini et al. PHYSICAL REVIEW D
- Quasinormal modes of nearly extremal Kerr spacetimes: Spectrum bifurcation and power-law ringdown
- (2013) Huan Yang et al. PHYSICAL REVIEW D
- Catalog of 174 Binary Black Hole Simulations for Gravitational Wave Astronomy
- (2013) Abdul H. Mroué et al. PHYSICAL REVIEW LETTERS
- Prototype effective-one-body model for nonprecessing spinning inspiral-merger-ringdown waveforms
- (2012) Andrea Taracchini et al. PHYSICAL REVIEW D
- Horizon-absorption effects in coalescing black-hole binaries: An effective-one-body study of the nonspinning case
- (2012) Sebastiano Bernuzzi et al. PHYSICAL REVIEW D
- Horizon-absorbed energy flux in circularized, nonspinning black-hole binaries, and its effective-one-body representation
- (2012) Alessandro Nagar et al. PHYSICAL REVIEW D
- Modeling multipolar gravitational-wave emission from small mass-ratio mergers
- (2012) Enrico Barausse et al. PHYSICAL REVIEW D
- Quasinormal-mode spectrum of Kerr black holes and its geometric interpretation
- (2012) Huan Yang et al. PHYSICAL REVIEW D
- Binary black hole coalescence in the extreme-mass-ratio limit: Testing and improving the effective-one-body multipolar waveform
- (2011) Sebastiano Bernuzzi et al. PHYSICAL REVIEW D
- New generic ringdown frequencies at the birth of a Kerr black hole
- (2011) Aaron Zimmerman et al. PHYSICAL REVIEW D
- Binary black hole coalescence in the large-mass-ratio limit: The hyperboloidal layer method and waveforms at null infinity
- (2011) Sebastiano Bernuzzi et al. PHYSICAL REVIEW D
- Inspiral-merger-ringdown multipolar waveforms of nonspinning black-hole binaries using the effective-one-body formalism
- (2011) Yi Pan et al. PHYSICAL REVIEW D
- Constructing effective one-body dynamics with numerical energy flux for intermediate-mass-ratio inspirals
- (2011) Wen-Biao Han et al. PHYSICAL REVIEW D
- Extreme mass-ratio inspirals in the effective-one-body approach: Quasicircular, equatorial orbits around a spinning black hole
- (2011) Nicolás Yunes et al. PHYSICAL REVIEW D
- Post-Newtonian factorized multipolar waveforms for spinning, nonprecessing black-hole binaries
- (2011) Yi Pan et al. PHYSICAL REVIEW D
- Mergers of black-hole binaries with aligned spins: Waveform characteristics
- (2011) Bernard J. Kelly et al. PHYSICAL REVIEW D
- Null Infinity Waveforms from Extreme-Mass-Ratio Inspirals in Kerr Spacetime
- (2011) Anıl Zenginoğlu et al. Physical Review X
- Binary black hole merger in the extreme-mass-ratio limit: A multipolar analysis
- (2010) Sebastiano Bernuzzi et al. PHYSICAL REVIEW D
- Effective-one-body waveforms calibrated to numerical relativity simulations: Coalescence of nonprecessing, spinning, equal-mass black holes
- (2010) Yi Pan et al. PHYSICAL REVIEW D
- Hidden conformal symmetry of the Kerr black hole
- (2010) Alejandra Castro et al. PHYSICAL REVIEW D
- Quasinormal mode spectrum of a Kerr black hole in the eikonal limit
- (2010) Sam R. Dolan PHYSICAL REVIEW D
- Quasinormal modes of black holes and black branes
- (2009) Emanuele Berti et al. CLASSICAL AND QUANTUM GRAVITY
- Improved resummation of post-Newtonian multipolar waveforms from circularized compact binaries
- (2009) Thibault Damour et al. PHYSICAL REVIEW D
- CFT duals for extreme black holes
- (2009) Thomas Hartman et al. JOURNAL OF HIGH ENERGY PHYSICS
- Anatomy of the binary black hole recoil: A multipolar analysis
- (2008) Jeremy D. Schnittman et al. PHYSICAL REVIEW D
- High-accuracy numerical simulation of black-hole binaries: Computation of the gravitational-wave energy flux and comparisons with post-Newtonian approximants
- (2008) Michael Boyle et al. PHYSICAL REVIEW D
- Towards adiabatic waveforms for inspiral into Kerr black holes. II. Dynamical sources and generic orbits
- (2008) Pranesh A. Sundararajan et al. PHYSICAL REVIEW D
- Mergers of nonspinning black-hole binaries: Gravitational radiation characteristics
- (2008) John G. Baker et al. PHYSICAL REVIEW D
- Gravitational radiation from plunging orbits: Perturbative study
- (2008) Yasushi Mino et al. PHYSICAL REVIEW D
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