Stochastic Gravitational Waves from Early Structure Formation

Nicolas Fernandez; Joshua W. Foster; Benjamin Lillard; Jessie Shelton

doi:10.1103/PhysRevLett.133.111002

Stochastic Gravitational Waves from Early Structure Formation

Nicolas Fernandez, Joshua W. Foster, Benjamin Lillard, Jessie Shelton

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Abstract

Early matter-dominated eras (EMDEs) are a natural feature arising in many models of the early Universe and can generate a stochastic gravitational wave background (SGWB) during the transition from an EMDE to the radiation-dominated universe required by the time of big bang nucleosynthesis. While there are calculations of the SGWB generated in the linear regime, no detailed study has been made of the nonlinear regime. We perform the first comprehensive calculation of gravitational wave (GW) production in EMDEs that are long enough that density contrasts grow to exceed unity, using a hybrid N-body and lattice simulation to study GW production from both a metastable matter species and the radiation produced in its decay. We find that nonlinearities significantly enhance GW production up to frequencies at least as large as the inverse light-crossing time of the largest halos that form prior to reheating. The resulting SGWB is within future observational reach for curvature perturbations as small as those probed in the cosmic microwave background, depending on the reheating temperature. Out-of-equilibrium dynamics could further boost the induced SGWB, while a fully relativistic gravitational treatment is required to resolve the spectrum at even higher frequencies.

Original language	English (US)
Article number	111002
Journal	Physical review letters
Volume	133
Issue number	11
Early online date	Sep 10 2024
DOIs	https://doi.org/10.1103/PhysRevLett.133.111002
State	Published - Sep 13 2024

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General Physics and Astronomy

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@article{7c81c535a27c400d90353aaea89ae134,

title = "Stochastic Gravitational Waves from Early Structure Formation",

abstract = "Early matter-dominated eras (EMDEs) are a natural feature arising in many models of the early Universe and can generate a stochastic gravitational wave background (SGWB) during the transition from an EMDE to the radiation-dominated universe required by the time of big bang nucleosynthesis. While there are calculations of the SGWB generated in the linear regime, no detailed study has been made of the nonlinear regime. We perform the first comprehensive calculation of gravitational wave (GW) production in EMDEs that are long enough that density contrasts grow to exceed unity, using a hybrid N-body and lattice simulation to study GW production from both a metastable matter species and the radiation produced in its decay. We find that nonlinearities significantly enhance GW production up to frequencies at least as large as the inverse light-crossing time of the largest halos that form prior to reheating. The resulting SGWB is within future observational reach for curvature perturbations as small as those probed in the cosmic microwave background, depending on the reheating temperature. Out-of-equilibrium dynamics could further boost the induced SGWB, while a fully relativistic gravitational treatment is required to resolve the spectrum at even higher frequencies.",

author = "Nicolas Fernandez and Foster, \{Joshua W.\} and Benjamin Lillard and Jessie Shelton",

note = "We particularly thank Jeppe Dakin for guidance regarding working with concept and feedback on the first version of our manuscript. We thank Malte Buschmann, Patrick Draper, Alan Guth, Misha Ivanov, Toby Opferkuch, Evangelos Sfakianakis, Victoria Tiki, and Helvi Witek for useful conversations. N.\textbackslash{}u2009F. is supported by the U.S. Department of Energy under Grant No. DE-SC0010008. J.\textbackslash{}u2009W.\textbackslash{}u2009F. was supported by a Pappalardo Fellowship. The work of B.\textbackslash{}u2009L. was supported in part by the U.S. Department of Energy under Grant No. DE-SC0011640. The work of J.\textbackslash{}u2009S. was supported in part by U.S. DOE Grants No. DE-SC0023365 and No. DE-SC0015655. This work used NCSA Delta CPU at UIUC through allocation PHY230051 from the Advanced Cyberinfrastructure Coordination Ecosystem: Services and Support (ACCESS) program, which is supported by National Science Foundation Grants No. 2138259, No. 2138286, No. 2138307, No. 2137603, and No. 2138296. J.\textbackslash{}u2009S. gratefully acknowledges MIT\textbackslash{}u2019s generous hospitality during the performance of this work. This research used resources of the Lawrencium computational cluster provided by the IT Division at the Lawrence Berkeley National Laboratory, both operated under Contract No. DE-AC02-05CH11231.",

year = "2024",

month = sep,

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doi = "10.1103/PhysRevLett.133.111002",

language = "English (US)",

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AU - Fernandez, Nicolas

AU - Foster, Joshua W.

AU - Lillard, Benjamin

AU - Shelton, Jessie

N1 - We particularly thank Jeppe Dakin for guidance regarding working with concept and feedback on the first version of our manuscript. We thank Malte Buschmann, Patrick Draper, Alan Guth, Misha Ivanov, Toby Opferkuch, Evangelos Sfakianakis, Victoria Tiki, and Helvi Witek for useful conversations. N.\u2009F. is supported by the U.S. Department of Energy under Grant No. DE-SC0010008. J.\u2009W.\u2009F. was supported by a Pappalardo Fellowship. The work of B.\u2009L. was supported in part by the U.S. Department of Energy under Grant No. DE-SC0011640. The work of J.\u2009S. was supported in part by U.S. DOE Grants No. DE-SC0023365 and No. DE-SC0015655. This work used NCSA Delta CPU at UIUC through allocation PHY230051 from the Advanced Cyberinfrastructure Coordination Ecosystem: Services and Support (ACCESS) program, which is supported by National Science Foundation Grants No. 2138259, No. 2138286, No. 2138307, No. 2137603, and No. 2138296. J.\u2009S. gratefully acknowledges MIT\u2019s generous hospitality during the performance of this work. This research used resources of the Lawrencium computational cluster provided by the IT Division at the Lawrence Berkeley National Laboratory, both operated under Contract No. DE-AC02-05CH11231.

PY - 2024/9/13

Y1 - 2024/9/13

N2 - Early matter-dominated eras (EMDEs) are a natural feature arising in many models of the early Universe and can generate a stochastic gravitational wave background (SGWB) during the transition from an EMDE to the radiation-dominated universe required by the time of big bang nucleosynthesis. While there are calculations of the SGWB generated in the linear regime, no detailed study has been made of the nonlinear regime. We perform the first comprehensive calculation of gravitational wave (GW) production in EMDEs that are long enough that density contrasts grow to exceed unity, using a hybrid N-body and lattice simulation to study GW production from both a metastable matter species and the radiation produced in its decay. We find that nonlinearities significantly enhance GW production up to frequencies at least as large as the inverse light-crossing time of the largest halos that form prior to reheating. The resulting SGWB is within future observational reach for curvature perturbations as small as those probed in the cosmic microwave background, depending on the reheating temperature. Out-of-equilibrium dynamics could further boost the induced SGWB, while a fully relativistic gravitational treatment is required to resolve the spectrum at even higher frequencies.

AB - Early matter-dominated eras (EMDEs) are a natural feature arising in many models of the early Universe and can generate a stochastic gravitational wave background (SGWB) during the transition from an EMDE to the radiation-dominated universe required by the time of big bang nucleosynthesis. While there are calculations of the SGWB generated in the linear regime, no detailed study has been made of the nonlinear regime. We perform the first comprehensive calculation of gravitational wave (GW) production in EMDEs that are long enough that density contrasts grow to exceed unity, using a hybrid N-body and lattice simulation to study GW production from both a metastable matter species and the radiation produced in its decay. We find that nonlinearities significantly enhance GW production up to frequencies at least as large as the inverse light-crossing time of the largest halos that form prior to reheating. The resulting SGWB is within future observational reach for curvature perturbations as small as those probed in the cosmic microwave background, depending on the reheating temperature. Out-of-equilibrium dynamics could further boost the induced SGWB, while a fully relativistic gravitational treatment is required to resolve the spectrum at even higher frequencies.

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Stochastic Gravitational Waves from Early Structure Formation

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