Primordial black hole archaeology with gravitational waves from cosmic strings

Ghoshal, Anish; Gouttenoire, Yann; Heurtier, Lucien; Simakachorn, Peera

doi:10.1007/jhep08(2023)196

Cited by 14 publications

(4 citation statements)

References 246 publications

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“…At least the NANOGrav data would still be consistent with such a scenario, our figure only ends at m a ∼ 10 −18 eV due to our choice of priors. Alternatively, also a period of late matter domination can improve the viability of the model, while still yielding observable GWs [92,94,167,168]. For completeness, let us also mention one further constraint, even though it is always weaker than N eff .…”

Section: Global (Alp) Stringsmentioning

confidence: 99%

Primordial gravitational waves in the nano-Hertz regime and PTA data — towards solving the GW inverse problem

Madge,

Morgante,

Puchades-Ibáñez

et al. 2023

J. High Energ. Phys.

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In recent years, several pulsar timing array collaborations have reported first hints for a stochastic gravitational wave background at nano-Hertz frequencies. Here we elaborate on the possibility that this signal comes from new physics that leads to the generation of a primordial stochastic gravitational wave background. We propose a set of simple but concrete models that can serve as benchmarks for gravitational waves sourced by cosmological phase transitions, domain wall networks, cosmic strings, axion dynamics, or large scalar fluctuations. These models are then confronted with pulsar timing data and with cosmological constraints. With only a limited number of free parameters per model, we are able to identify viable regions of parameter space and also make predictions for future astrophysical and laboratory tests that can help with model identification and discrimination.

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Section: Global (Alp) Stringsmentioning

confidence: 99%

Primordial gravitational waves in the nano-Hertz regime and PTA data — towards solving the GW inverse problem

Madge,

Morgante,

Puchades-Ibáñez

et al. 2023

J. High Energ. Phys.

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“…Potential cosmic sources could produce gravitational waves in the nHz frequency range [9][10][11][12][13][14][15][16][17]. However, despite hopes that these gravitational waves could be generated by new physics phenomena, the observed amplitude and spectral slope are approximately consistent with the astrophysical background.…”

Section: Introductionmentioning

confidence: 99%

Probing the Dark Matter density with gravitational waves from super-massive binary black holes

Ghoshal,

Strumia

2024

J. Cosmol. Astropart. Phys.

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Supermassive black hole binaries source gravitational waves measured by Pulsar Timing Arrays. The frequency spectrum of this stochastic background is predicted more precisely than its amplitude. We argue that Dark Matter friction can suppress the spectrum around nHz frequencies, where it is measured, allowing to derive robust and significant bounds on the Dark Matter density, which, in turn, controls indirect detection signals from galactic centers. A precise spectrum of gravitational waves would translate in a tomography of the DM density profile, potentially probing DM particle-physics effects that induce a characteristic DM density profile, such as DM annihilations or de Broglie wavelength.

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“…Moreover, many potential transient GW sources, like cosmic strings or primordial black holes remain challenging to define due to the intricate and speculative nature of these phenomena. Recent studies have delved into the dynamics and potential gravitational wave emissions from these sources, but the precise characterization of their signals is still an area of active research and exploration [21,22]. Hence, there is a growing need to develop innovative detection strategies capable of identifying these elusive and potentially groundbreaking signals.…”

Section: Introductionmentioning

confidence: 99%

GWAK: gravitational-wave anomalous knowledge with recurrent autoencoders

Raikman,

Moreno,

Govorkova

et al. 2024

Mach. Learn.: Sci. Technol.

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Matched-filtering detection techniques for gravitational-wave (GW) signals in ground-based interferometers rely on having well-modeled templates of the GW emission. Such techniques have been traditionally used in searches for compact binary coalescences (CBCs), and have been employed in all known GW detections so far. However, interesting science cases aside from compact mergers do not yet have accurate enough modeling to make matched filtering possible, including core-collapse supernovae and sources where stochasticity may be involved. Therefore the development of techniques to identify sources of these types is of significant interest. In this paper, we present a method of anomaly detection based on deep recurrent autoencoders to enhance the search region to unmodeled transients. We use a semi-supervised strategy that we name “Gravitational Wave Anomalous Knowledge” (GWAK). While the semi-supervised nature of the problem comes with a cost in terms of accuracy as compared to supervised techniques, there is a qualitative advantage in generalizing experimental sensitivity beyond pre-computed signal templates. We construct a low-dimensional embedded space using the GWAK method, capturing the physical signatures of distinct signals on each axis of the space. By introducing signal priors that capture some of the salient features of GW signals, we allow for the recovery of sensitivity even when an unmodeled anomaly is encountered. We show that regions of the GWAK space can identify CBCs, detector glitches and also a variety of unmodeled astrophysical sources.

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Primordial black hole archaeology with gravitational waves from cosmic strings

Cited by 14 publications

References 246 publications

Primordial gravitational waves in the nano-Hertz regime and PTA data — towards solving the GW inverse problem

Primordial gravitational waves in the nano-Hertz regime and PTA data — towards solving the GW inverse problem

Probing the Dark Matter density with gravitational waves from super-massive binary black holes

GWAK: gravitational-wave anomalous knowledge with recurrent autoencoders

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