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Main Authors: Su, Henry, Brown, Lucas, Ewasiuk, Christopher, Profumo, Stefano
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.01407
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author Su, Henry
Brown, Lucas
Ewasiuk, Christopher
Profumo, Stefano
author_facet Su, Henry
Brown, Lucas
Ewasiuk, Christopher
Profumo, Stefano
contents Ultralight bosons can form macroscopic gravitational-atom clouds around rotating black holes via superradiance, sourcing quasi-monochromatic gravitational waves through level transitions and annihilation. Primordial black holes provide a natural setting for such systems in a frequency range relevant for resonant-cavity experiments. We present a unified treatment of gravitational-wave emission from both isolated and binary-perturbed gravitational atoms in this regime. For isolated systems, we derive analytic expressions for the time- and frequency-domain strain from transition and annihilation channels, emphasizing their narrow-band structure. For binaries, we model resonantly driven level transitions using the Landau--Zener formalism and compute the resulting transient signals. We find that, while binary-driven transitions generically yield signals with durations compatible with detector response times, their characteristic strain lies well below the sensitivity of current experiments at astrophysically plausible distances, and event rates further suppress detectability by requiring sources at unrealistically small separations. We quantify the improvements in sensitivity, bandwidth, and response needed to render these signals observable, and identify gravitational-atom systems around primordial black holes as a theoretically well-motivated target for future high-frequency gravitational-wave searches.
format Preprint
id arxiv_https___arxiv_org_abs_2604_01407
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle High-frequency gravitational wave transients from superradiance
Su, Henry
Brown, Lucas
Ewasiuk, Christopher
Profumo, Stefano
General Relativity and Quantum Cosmology
Ultralight bosons can form macroscopic gravitational-atom clouds around rotating black holes via superradiance, sourcing quasi-monochromatic gravitational waves through level transitions and annihilation. Primordial black holes provide a natural setting for such systems in a frequency range relevant for resonant-cavity experiments. We present a unified treatment of gravitational-wave emission from both isolated and binary-perturbed gravitational atoms in this regime. For isolated systems, we derive analytic expressions for the time- and frequency-domain strain from transition and annihilation channels, emphasizing their narrow-band structure. For binaries, we model resonantly driven level transitions using the Landau--Zener formalism and compute the resulting transient signals. We find that, while binary-driven transitions generically yield signals with durations compatible with detector response times, their characteristic strain lies well below the sensitivity of current experiments at astrophysically plausible distances, and event rates further suppress detectability by requiring sources at unrealistically small separations. We quantify the improvements in sensitivity, bandwidth, and response needed to render these signals observable, and identify gravitational-atom systems around primordial black holes as a theoretically well-motivated target for future high-frequency gravitational-wave searches.
title High-frequency gravitational wave transients from superradiance
topic General Relativity and Quantum Cosmology
url https://arxiv.org/abs/2604.01407