Unveiling hidden variability components in accreting X-ray binaries using both the Fourier power and cross spectra
Unveiling hidden variability components in accreting X-ray binaries using both the Fourier power and cross spectra
We present a novel method for measuring the lags of (weak) variability components in neutron-star and black-hole low-mass X-ray binaries (LMXBs). For this we assume that the power and cross spectra of these sources consists of a number of components that are coherent in different energy bands, but are incoherent with one another. The technique is based on fitting simultaneously the power spectrum (PS) and the Real and Imaginary parts of the cross spectrum (CS) with a combination of Lorentzian functions. We show that, because the PS of LMXBs is insensitive to signals with a large Imaginary part and a small Real part in the CS, this approach allows us to uncover new variability components that are only detected in the CS. We also demonstrate that, contrary to earlier claims, the frequency of the type-C quasi-periodic oscillation (QPO) in the black-hole binary GRS 1915+105 does not depend on energy. Rather, the apparent energy dependence of the QPO frequency can be explained by the presence of a separate QPO component with a slightly higher frequency than that of the QPO, whose rms amplitude increases faster with energy than the rms amplitude of the QPO. From all the above we conclude that, as in the case of the PS, the CS of black-hole and neutron-star binaries can be fitted by a combination of Lorentzian components. Our findings provide evidence that the frequency-dependent part of the transfer function of these systems can be described by a combination of responses, each of them acting over relatively well-defined time scales. This conclusion challenges models that assume that the main contribution to the lags comes from a global, broadband, transfer function of the accreting system.
astro-ph.HE
Mendez, Mariano
d28e6a32-ba07-4267-a01c-a349f674b3ad
Peirano, Valentina
4981c64a-f74c-4993-abab-245ee9803523
Garcia, Federico
302a7676-0d2d-4f27-afd6-4c23adbcdfa4
Belloni, Tomaso M.
bbd7ff5b-da7d-4d6b-b528-d995de790e3e
Altamirano, Diego
d5ccdb09-0b71-4303-9538-05b467be075b
Alabarta, Kevin
8c164ccd-de85-4b2b-870b-7471ff95423b
Mendez, Mariano
d28e6a32-ba07-4267-a01c-a349f674b3ad
Peirano, Valentina
4981c64a-f74c-4993-abab-245ee9803523
Garcia, Federico
302a7676-0d2d-4f27-afd6-4c23adbcdfa4
Belloni, Tomaso M.
bbd7ff5b-da7d-4d6b-b528-d995de790e3e
Altamirano, Diego
d5ccdb09-0b71-4303-9538-05b467be075b
Alabarta, Kevin
8c164ccd-de85-4b2b-870b-7471ff95423b
[Unknown type: UNSPECIFIED]
Abstract
We present a novel method for measuring the lags of (weak) variability components in neutron-star and black-hole low-mass X-ray binaries (LMXBs). For this we assume that the power and cross spectra of these sources consists of a number of components that are coherent in different energy bands, but are incoherent with one another. The technique is based on fitting simultaneously the power spectrum (PS) and the Real and Imaginary parts of the cross spectrum (CS) with a combination of Lorentzian functions. We show that, because the PS of LMXBs is insensitive to signals with a large Imaginary part and a small Real part in the CS, this approach allows us to uncover new variability components that are only detected in the CS. We also demonstrate that, contrary to earlier claims, the frequency of the type-C quasi-periodic oscillation (QPO) in the black-hole binary GRS 1915+105 does not depend on energy. Rather, the apparent energy dependence of the QPO frequency can be explained by the presence of a separate QPO component with a slightly higher frequency than that of the QPO, whose rms amplitude increases faster with energy than the rms amplitude of the QPO. From all the above we conclude that, as in the case of the PS, the CS of black-hole and neutron-star binaries can be fitted by a combination of Lorentzian components. Our findings provide evidence that the frequency-dependent part of the transfer function of these systems can be described by a combination of responses, each of them acting over relatively well-defined time scales. This conclusion challenges models that assume that the main contribution to the lags comes from a global, broadband, transfer function of the accreting system.
Text
2312.03476v1
- Author's Original
More information
Accepted/In Press date: 6 December 2023
Additional Information:
13 figures, 6 tables; accepted for publication in MNRAS
Keywords:
astro-ph.HE
Identifiers
Local EPrints ID: 486403
URI: http://eprints.soton.ac.uk/id/eprint/486403
PURE UUID: 7f23015f-01f1-42c2-9765-cd9856b56af7
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Date deposited: 19 Jan 2024 17:40
Last modified: 18 Mar 2024 03:27
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Contributors
Author:
Mariano Mendez
Author:
Valentina Peirano
Author:
Federico Garcia
Author:
Tomaso M. Belloni
Author:
Kevin Alabarta
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