Impact of signal clusters in wide-band searches for continuous gravitational waves

TL;DR

This study evaluates the robustness of the hierarchical frequency-Hough pipeline in detecting continuous gravitational waves, especially under conditions of signal clusters from multiple sources within narrow frequency ranges, relevant for future detectors.

Contribution

It provides a quantitative analysis of the frequency-Hough pipeline's performance in scenarios with dense signal clusters, highlighting its robustness and potential sensitivity variations.

Findings

Small sensitivity loss with high-density signal clusters over ~1 Hz.

Potential sensitivity gain when clusters cover less than 0.1 Hz.

Robustness of the frequency-Hough method in moderate-to-large cluster scenarios.

Abstract

In this paper we present a study of some relevant steps of the hierarchical frequency-Hough (FH) pipeline, used within the LIGO and Virgo Collaborations for wide-parameter space searches of continuous gravitational waves (CWs) emitted, for instance, by spinning neutron stars (NSs). Because of their weak expected amplitudes, CWs have not been still detected so far. These steps, namely the spectral estimation, the {\it peakmap} construction and the procedure to select candidates in the FH plane, are critical as they contribute to determine the final search sensitivity. Here, we are interested in investigating their behavior in the (presently quite) extreme case of signal clusters, due to many and strong CW sources, emitting gravitational waves (GWs) within a small (i.e. <1 Hz wide) frequency range. This could happen for some kinds of CW sources detectable by next generation detectors, like LISA, Einstein Telescope and Cosmic Explorer. Moreover, this possibility has been recently raised even for current Earth-based detectors, in some scenarios of CW emission from ultralight boson clouds around stellar mass black holes (BHs). We quantitatively evaluate the robustness of the FH analysis procedure, designed to minimize the loss of single CW signals, under the unusual situation of signal clusters. Results depend mainly on how strong in amplitude and dense in frequency the signals are, and on the range of frequency they cover. We show that indeed a small sensitivity loss may happen in presence of a very high mean signal density affecting a frequency range of the order of one Hertz, while when the signal cluster covers a frequency range of one tenth of Hertz, or less, we may actually have a sensitivity gain. Overall, we demonstrate the FH to be robust even in presence of moderate-to-large signal clusters.