Gravitational Wave Constraints on Planetary-Mass Primordial Black Holes Using LIGO O3a Data

Andrew L. Miller*, Nancy Aggarwal*, Sébastien Clesse, Federico De Lillo, Surabhi Sachdev, Pia Astone, Cristiano Palomba, Ornella J. Piccinni, Lorenzo Pierini

*Corresponding author for this work

Research output: Contribution to journalArticleAcademicpeer-review

Abstract

Gravitational waves from subsolar mass inspiraling compact objects would provide almost smoking-gun evidence for primordial black holes (PBHs). We perform the first search for inspiraling planetary-mass compact objects in equal-mass and highly asymmetric mass-ratio binaries using data from the first half of the LIGO-Virgo-KAGRA third observing run. Though we do not find any significant candidates, we determine the maximum luminosity distance reachable with our search to be of O(0.1-100) kpc, and corresponding model-independent upper limits on the merger rate densities to be O(103-10-7) kpc-3 yr-1 for systems with chirp masses of O(10-4-10-2)M⊙, respectively. Furthermore, we interpret these rate densities as arising from PBH binaries and constrain the fraction of dark matter that such objects could comprise. For equal-mass PBH binaries, we find that these objects would compose less than 4%-100% of DM for PBH masses of 10-2M⊙ to 2×10-3M⊙, respectively. For asymmetric binaries, assuming one black hole mass corresponds to a peak in the mass function at 2.5M⊙, a PBH dark-matter fraction of 10% and a second, much lighter PBH, we constrain the mass function of the second PBH to be less than 1 for masses between 1.5×10-5M⊙ and 2×10-4M⊙. Our constraints, recently released, are robust enough to be applied to any PBH or exotic compact object binary formation models, and complement existence microlensing results.

Original languageEnglish
Article number111401
Number of pages7
JournalPhysical Review Letters
Volume133
Issue number11
DOIs
Publication statusPublished - 13 Sept 2024

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