Event rate estimates for LISA extreme mass ratio capture sources

Jonathan R. Gair; Leor Barack; Teviet Creighton; Curt Cutler; Shane L. Larson; E. Sterl Phinney; Michele Vallisneri

doi:10.1088/0264-9381/21/20/003

Event rate estimates for LISA extreme mass ratio capture sources

Jonathan R. Gair^*, Leor Barack, Teviet Creighton, Curt Cutler, Shane L. Larson, E. Sterl Phinney, Michele Vallisneri

^*Corresponding author for this work

Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

214 Scopus citations

Abstract

One of the most exciting prospects for the LISA gravitational wave observatory is the detection of gravitational radiation from the inspiral of a compact object into a supermassive black hole. The large inspirai parameter space and low amplitude of the signal make detection of these sources computationally challenging. We outline here a first-cut data analysis scheme that assumes realistic computational resources. In the context of this scheme, we estimate the signal-to-noise ratio that a source requires to pass our thresholds and be detected. Combining this with an estimate of the population of sources in the universe, we estimate the number of inspirai events that LISA could detect. The preliminary results are very encouraging - with the baseline design, LISA can see inspirals out to a redshift z = 1 and should detect over a thousand events during the mission lifetime.

Original language	English (US)
Pages (from-to)	S1595-S1606
Journal	Classical and Quantum Gravity
Volume	21
Issue number	20 SPEC. ISS.
DOIs	https://doi.org/10.1088/0264-9381/21/20/003
State	Published - Oct 21 2004

ASJC Scopus subject areas

Physics and Astronomy (miscellaneous)

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Cite this

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title = "Event rate estimates for LISA extreme mass ratio capture sources",

abstract = "One of the most exciting prospects for the LISA gravitational wave observatory is the detection of gravitational radiation from the inspiral of a compact object into a supermassive black hole. The large inspirai parameter space and low amplitude of the signal make detection of these sources computationally challenging. We outline here a first-cut data analysis scheme that assumes realistic computational resources. In the context of this scheme, we estimate the signal-to-noise ratio that a source requires to pass our thresholds and be detected. Combining this with an estimate of the population of sources in the universe, we estimate the number of inspirai events that LISA could detect. The preliminary results are very encouraging - with the baseline design, LISA can see inspirals out to a redshift z = 1 and should detect over a thousand events during the mission lifetime.",

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T1 - Event rate estimates for LISA extreme mass ratio capture sources

AU - Gair, Jonathan R.

AU - Barack, Leor

AU - Creighton, Teviet

AU - Cutler, Curt

AU - Larson, Shane L.

AU - Phinney, E. Sterl

AU - Vallisneri, Michele

PY - 2004/10/21

Y1 - 2004/10/21

N2 - One of the most exciting prospects for the LISA gravitational wave observatory is the detection of gravitational radiation from the inspiral of a compact object into a supermassive black hole. The large inspirai parameter space and low amplitude of the signal make detection of these sources computationally challenging. We outline here a first-cut data analysis scheme that assumes realistic computational resources. In the context of this scheme, we estimate the signal-to-noise ratio that a source requires to pass our thresholds and be detected. Combining this with an estimate of the population of sources in the universe, we estimate the number of inspirai events that LISA could detect. The preliminary results are very encouraging - with the baseline design, LISA can see inspirals out to a redshift z = 1 and should detect over a thousand events during the mission lifetime.

AB - One of the most exciting prospects for the LISA gravitational wave observatory is the detection of gravitational radiation from the inspiral of a compact object into a supermassive black hole. The large inspirai parameter space and low amplitude of the signal make detection of these sources computationally challenging. We outline here a first-cut data analysis scheme that assumes realistic computational resources. In the context of this scheme, we estimate the signal-to-noise ratio that a source requires to pass our thresholds and be detected. Combining this with an estimate of the population of sources in the universe, we estimate the number of inspirai events that LISA could detect. The preliminary results are very encouraging - with the baseline design, LISA can see inspirals out to a redshift z = 1 and should detect over a thousand events during the mission lifetime.

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Event rate estimates for LISA extreme mass ratio capture sources

Abstract

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