Practical approaches to analyzing PTA data: Cosmic strings with six pulsars

(European Pulsar Timing Array)

doi:10.1103/PhysRevD.108.123527

Practical approaches to analyzing PTA data: Cosmic strings with six pulsars

(European Pulsar Timing Array)

Research output: Contribution to a Journal (Peer & Non Peer) › Article › peer-review

9 Citations (Scopus)

Abstract

We search for a stochastic gravitational wave background (SGWB) generated by a network of cosmic strings using six millisecond pulsars from Data Release 2 (DR2) of the European Pulsar Timing Array (EPTA). We perform a Bayesian analysis considering two models for the network of cosmic string loops, and compare it to a simple power-law model which is expected from the population of supermassive black hole binaries. Our main strong assumption is that the previously reported common red noise process is a SGWB. We find that the one-parameter cosmic string model is slightly favored over a power-law model thanks to its simplicity. If we assume a two-component stochastic signal in the data (supermassive black hole binary population and the signal from cosmic strings), we get a 95% upper limit on the string tension of log10(Gμ)<-9.9 (-10.5) for the two cosmic string models we consider. In extended two-parameter string models, we were unable to constrain the number of kinks. We test two approximate and fast Bayesian data analysis methods against the most rigorous analysis and find consistent results. These two fast and efficient methods are applicable to all SGWBs, independent of their source, and will be crucial for analysis of extended datasets.

Original language	English
Article number	123527
Journal	Physical Review D
Volume	108
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevD.108.123527
Publication status	Published - 15 Dec 2023
Externally published	Yes

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10.1103/PhysRevD.108.123527

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@article{d77b0d2c00c9461898c5e21c65b15b4b,

title = "Practical approaches to analyzing PTA data: Cosmic strings with six pulsars",

abstract = "We search for a stochastic gravitational wave background (SGWB) generated by a network of cosmic strings using six millisecond pulsars from Data Release 2 (DR2) of the European Pulsar Timing Array (EPTA). We perform a Bayesian analysis considering two models for the network of cosmic string loops, and compare it to a simple power-law model which is expected from the population of supermassive black hole binaries. Our main strong assumption is that the previously reported common red noise process is a SGWB. We find that the one-parameter cosmic string model is slightly favored over a power-law model thanks to its simplicity. If we assume a two-component stochastic signal in the data (supermassive black hole binary population and the signal from cosmic strings), we get a 95\% upper limit on the string tension of log10(Gμ)<-9.9 (-10.5) for the two cosmic string models we consider. In extended two-parameter string models, we were unable to constrain the number of kinks. We test two approximate and fast Bayesian data analysis methods against the most rigorous analysis and find consistent results. These two fast and efficient methods are applicable to all SGWBs, independent of their source, and will be crucial for analysis of extended datasets.",

author = "\{(European Pulsar Timing Array)\} and \{Quelquejay Leclere\}, Hippolyte and Pierre Auclair and Stanislav Babak and Aur{\'e}lien Chalumeau and Steer, \{Dani{\`e}le A.\} and J. Antoniadis and Nielsen, \{A. S.Bak\} and Bassa, \{C. G.\} and A. Berthereau and M. Bonetti and E. Bortolas and Brook, \{P. R.\} and M. Burgay and Caballero, \{R. N.\} and Champion, \{D. J.\} and S. Chanlaridis and S. Chen and I. Cognard and G. Desvignes and M. Falxa and Ferdman, \{R. D.\} and A. Franchini and Gair, \{J. R.\} and B. Goncharov and E. Graikou and Grie{\ss}meier, \{J. M.\} and L. Guillemot and Guo, \{Y. J.\} and H. Hu and F. Iraci and D. Izquierdo-Villalba and J. Jang and J. Jawor and Janssen, \{G. H.\} and A. Jessner and R. Karuppusamy and Keane, \{E. F.\} and Keith, \{M. J.\} and M. Kramer and Krishnakumar, \{M. A.\} and K. Lackeos and Lee, \{K. J.\} and K. Liu and Y. Liu and Lyne, \{A. G.\} and McKee, \{J. W.\} and Main, \{R. A.\} and Mickaliger, \{M. B.\} and Ni{\c t}u, \{I. C.\} and A. Parthasarathy and Perera, \{B. B.P.\} and D. Perrodin and A. Petiteau and Porayko, \{N. K.\} and A. Possenti and A. Samajdar and Sanidas, \{S. A.\} and A. Sesana and G. Shaifullah and L. Speri and R. Spiewak and Stappers, \{B. W.\} and Susarla, \{S. C.\} and G. Theureau and C. Tiburzi and \{Van Der Wateren\}, E. and A. Vecchio and Krishnan, \{V. Venkatraman\} and J. Wang and L. Wang and Z. Wu",

note = "Publisher Copyright: {\textcopyright} 2023 American Physical Society.",

year = "2023",

month = dec,

day = "15",

doi = "10.1103/PhysRevD.108.123527",

language = "English",

volume = "108",

journal = "Physical Review D",

issn = "2470-0010",

publisher = "American Physical Society",

number = "12",

}

TY - JOUR

T1 - Practical approaches to analyzing PTA data

T2 - Cosmic strings with six pulsars

AU - (European Pulsar Timing Array)

AU - Quelquejay Leclere, Hippolyte

AU - Auclair, Pierre

AU - Babak, Stanislav

AU - Chalumeau, Aurélien

AU - Steer, Danièle A.

AU - Antoniadis, J.

AU - Nielsen, A. S.Bak

AU - Bassa, C. G.

AU - Berthereau, A.

AU - Bonetti, M.

AU - Bortolas, E.

AU - Brook, P. R.

AU - Burgay, M.

AU - Caballero, R. N.

AU - Champion, D. J.

AU - Chanlaridis, S.

AU - Chen, S.

AU - Cognard, I.

AU - Desvignes, G.

AU - Falxa, M.

AU - Ferdman, R. D.

AU - Franchini, A.

AU - Gair, J. R.

AU - Goncharov, B.

AU - Graikou, E.

AU - Grießmeier, J. M.

AU - Guillemot, L.

AU - Guo, Y. J.

AU - Hu, H.

AU - Iraci, F.

AU - Izquierdo-Villalba, D.

AU - Jang, J.

AU - Jawor, J.

AU - Janssen, G. H.

AU - Jessner, A.

AU - Karuppusamy, R.

AU - Keane, E. F.

AU - Keith, M. J.

AU - Kramer, M.

AU - Krishnakumar, M. A.

AU - Lackeos, K.

AU - Lee, K. J.

AU - Liu, K.

AU - Liu, Y.

AU - Lyne, A. G.

AU - McKee, J. W.

AU - Main, R. A.

AU - Mickaliger, M. B.

AU - Niţu, I. C.

AU - Parthasarathy, A.

AU - Perera, B. B.P.

AU - Perrodin, D.

AU - Petiteau, A.

AU - Porayko, N. K.

AU - Possenti, A.

AU - Samajdar, A.

AU - Sanidas, S. A.

AU - Sesana, A.

AU - Shaifullah, G.

AU - Speri, L.

AU - Spiewak, R.

AU - Stappers, B. W.

AU - Susarla, S. C.

AU - Theureau, G.

AU - Tiburzi, C.

AU - Van Der Wateren, E.

AU - Vecchio, A.

AU - Krishnan, V. Venkatraman

AU - Wang, J.

AU - Wang, L.

AU - Wu, Z.

PY - 2023/12/15

Y1 - 2023/12/15

N2 - We search for a stochastic gravitational wave background (SGWB) generated by a network of cosmic strings using six millisecond pulsars from Data Release 2 (DR2) of the European Pulsar Timing Array (EPTA). We perform a Bayesian analysis considering two models for the network of cosmic string loops, and compare it to a simple power-law model which is expected from the population of supermassive black hole binaries. Our main strong assumption is that the previously reported common red noise process is a SGWB. We find that the one-parameter cosmic string model is slightly favored over a power-law model thanks to its simplicity. If we assume a two-component stochastic signal in the data (supermassive black hole binary population and the signal from cosmic strings), we get a 95% upper limit on the string tension of log10(Gμ)<-9.9 (-10.5) for the two cosmic string models we consider. In extended two-parameter string models, we were unable to constrain the number of kinks. We test two approximate and fast Bayesian data analysis methods against the most rigorous analysis and find consistent results. These two fast and efficient methods are applicable to all SGWBs, independent of their source, and will be crucial for analysis of extended datasets.

AB - We search for a stochastic gravitational wave background (SGWB) generated by a network of cosmic strings using six millisecond pulsars from Data Release 2 (DR2) of the European Pulsar Timing Array (EPTA). We perform a Bayesian analysis considering two models for the network of cosmic string loops, and compare it to a simple power-law model which is expected from the population of supermassive black hole binaries. Our main strong assumption is that the previously reported common red noise process is a SGWB. We find that the one-parameter cosmic string model is slightly favored over a power-law model thanks to its simplicity. If we assume a two-component stochastic signal in the data (supermassive black hole binary population and the signal from cosmic strings), we get a 95% upper limit on the string tension of log10(Gμ)<-9.9 (-10.5) for the two cosmic string models we consider. In extended two-parameter string models, we were unable to constrain the number of kinks. We test two approximate and fast Bayesian data analysis methods against the most rigorous analysis and find consistent results. These two fast and efficient methods are applicable to all SGWBs, independent of their source, and will be crucial for analysis of extended datasets.

UR - http://www.scopus.com/inward/record.url?scp=85180315313&partnerID=8YFLogxK

U2 - 10.1103/PhysRevD.108.123527

DO - 10.1103/PhysRevD.108.123527

M3 - Article

AN - SCOPUS:85180315313

SN - 2470-0010

VL - 108

JO - Physical Review D

JF - Physical Review D

IS - 12

M1 - 123527

ER -

Practical approaches to analyzing PTA data: Cosmic strings with six pulsars

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