Fast X-ray/IR observations of the black hole transient Swift~J1753.5--0127: from an IR lead to a very long jet lag

Alberto Ulgiati; Federico Maria Vincentelli; Piergiorgio Casella; Alexandra Veledina; Thomas Maccarone; David Russell; Phil Uttley; Filippo Ambrosino; Maria Cristina Baglio; Matteo Imbrogno; Andrea Melandri; Sara Elisa Motta; Kiran O'Brien; Andrea Sanna; Tariq Shahbaz; Diego Altamirano; Rob Fender; Dipankar Maitra; Julien Malzac

doi:10.1051/0004-6361/202450545

Fast X-ray/IR observations of the black hole transient Swift~J1753.5--0127: from an IR lead to a very long jet lag

Alberto Ulgiati, Federico Maria Vincentelli, Piergiorgio Casella, Alexandra Veledina, Thomas Maccarone, David Russell, Phil Uttley, Filippo Ambrosino, Maria Cristina Baglio, Matteo Imbrogno, Andrea Melandri, Sara Elisa Motta, Kiran O'Brien, Andrea Sanna, Tariq Shahbaz, Diego Altamirano, Rob Fender, Dipankar Maitra, Julien Malzac

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

We report on two epochs of simultaneous near-infrared (IR) and X-ray observations with a sub-second time resolution of the low mass X-ray binary black hole candidate Swift J1753.5--0127 during its long 2005--2016 outburst. Data were collected strictly simultaneously with VLT/ISAAC (K$_{S}$ band, 2.2 $μm$) and RXTE (2-15 keV) or \textit{XMM-Newton} (0.7-10 keV). A clear correlation between the X-ray and the IR variable emission is found during both epochs but with very different properties. In the first epoch, the near-IR variability leads the X-ray by $ \sim 130 \, ms$. This is the opposite of what is usually observed in similar systems. The correlation is more complex in the second epoch, with both anti-correlation and correlations at negative and positive lags. Frequency-resolved Fourier analysis allows us to identify two main components in the complex structure of the phase lags: the first component, characterised by a few seconds near-IR lag at low frequencies, is consistent with a combination of disc reprocessing and a magnetised hot flow; the second component is identified at high frequencies by a near-IR lag of $\approx$0.7 s. Given the similarities of this second component with the well-known constant optical/near-IR jet lag observed in other black hole transients, we tentatively interpret this feature as a signature of a longer-than-usual jet lag. We discuss the possible implications of measuring such a long jet lag in a radio-quiet black hole transient.

Original language	English
Article number	A239
Number of pages	10
Journal	Astronomy & Astrophysics
Volume	690
Early online date	14 Oct 2024
DOIs	https://doi.org/10.1051/0004-6361/202450545
Publication status	E-pub ahead of print - 14 Oct 2024
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2024 The Authors.

Funding

Based on observations collected at the European Southern Observatory under ESO programmes 281.D-5034 and 089.C-0996. PC, FMV and all the Authors acknowledge the long-term contribution of Tomaso Belloni to this project. Tomaso sadly passed away in August 2023 and will be sorely missed. The Authors thank the Team Meeting at the International Space Science Institute (Bern) for fruitful discussions and were supported by the ISSI International Team project #440. FMV acknowledges support from the grant FJC2020-043334-I financed by MCIN/AEI/10.13039/501100011033 and Next Generation EU/PRTR, as well as from the grant PID2020-114822GB-I00. PC acknowledges financial support from the Italian Space Agency and National Institute for Astrophysics, ASI/INAF, under agreement ASI-INAF n.2017-14- H.0. AV acknowledges support from the Research Council of Finland grant 355672. Nordita is supported in part by NordForsk. MI is supported by the AASS Ph.D. joint research programme between the University of Rome Sapienza and the University of Rome Tor Vergata , with the collaboration of the National Institute of Astrophysics (INAF). Based on observations collected at the European Southern Observatory under ESO programmes 281.D-5034 and 089.C-0996. PC, FMV and all the Authors acknowledge the long-term contribution of Tomaso Belloni to this project. Tomaso sadly passed away in August 2023 and will be sorely missed. The Authors thank the Team Meeting at the International Space Science Institute (Bern) for fruitful discussions and were supported by the ISSI International Team project #440. FMV acknowledges support from the grant FJC2020-043334-I financed by MCIN/AEI/10.13039/501100011033 and Next Generation EU/PRTR, as well as from the grant PID2020-114822GB-I00. PC acknowledges financial support from the Italian Space Agency and National Institute for Astrophysics, ASI/INAF, under agreement ASI-INAF n.2017-14-H.0. AV acknowledges support from the Research Council of Finland grant 355672. Nordita is supported in part by NordForsk. MI is supported by the AASS Ph.D. joint research programme between the University of Rome “Sapienza” and the University of Rome “Tor Vergata”, with the collaboration of the National Institute of Astrophysics (INAF). The ISAAC data are available from the ESO Data Archive ( https://archive.eso.org/eso/eso_archive_main.html ). The RXTE data are available from the HEASARC Data Archive ( https://heasarc.gsfc.nasa.gov/docs/archive.html ). The XMM-Newton data are available from the XMM-Newton Science Archive ( https://nxsa.esac.esa.int/nxsa-web/ ). The MAXI data used in Fig.1 are available from the MAXI website ( http://maxi.riken.jp/top/index.html ). The BAT data used to estimate the hardness of the source during the second epoch are available from the Neil Gehrels Swift Observatory archive ( https://swift.gsfc.nasa.gov/results/transients/ ).

Funders	Funder number
Agenzia Spaziale Italiana
Sapienza University of Rome
Fundación Marqués de Valdecilla
NordForsk
National Institute for Astrophysics
International Space Science Institute	FJC2020-043334-I, 440, MCIN/AEI/10.13039/501100011033, PID2020-114822GB-I00
Research Council of Finland	355672

Keywords

Stars: activity
Stars: black holes
Stars: evolution
Stars: jets

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

Access to Document

10.1051/0004-6361/202450545Licence: CC BY

aa50545-24Final published version, 898 KBLicence: CC BY
2407.00195v1

Cite this

Ulgiati, A., Vincentelli, F. M., Casella, P., Veledina, A., Maccarone, T., Russell, D., Uttley, P., Ambrosino, F., Baglio, M. C., Imbrogno, M., Melandri, A., Motta, S. E., O'Brien, K., Sanna, A., Shahbaz, T., Altamirano, D., Fender, R., Maitra, D., & Malzac, J. (2024). Fast X-ray/IR observations of the black hole transient Swift~J1753.5--0127: from an IR lead to a very long jet lag. Astronomy & Astrophysics, 690, Article A239. Advance online publication. https://doi.org/10.1051/0004-6361/202450545

Ulgiati, A, Vincentelli, FM, Casella, P, Veledina, A, Maccarone, T, Russell, D, Uttley, P, Ambrosino, F, Baglio, MC, Imbrogno, M, Melandri, A, Motta, SE, O'Brien, K, Sanna, A, Shahbaz, T, Altamirano, D, Fender, R, Maitra, D & Malzac, J 2024, 'Fast X-ray/IR observations of the black hole transient Swift~J1753.5--0127: from an IR lead to a very long jet lag', Astronomy & Astrophysics, vol. 690, A239. https://doi.org/10.1051/0004-6361/202450545

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title = "Fast X-ray/IR observations of the black hole transient Swift\textasciitilde{}J1753.5--0127: from an IR lead to a very long jet lag",

abstract = "We report on two epochs of simultaneous near-infrared (IR) and X-ray observations with a sub-second time resolution of the low mass X-ray binary black hole candidate Swift J1753.5--0127 during its long 2005--2016 outburst. Data were collected strictly simultaneously with VLT/ISAAC (K\$\_\{S\}\$ band, 2.2 \$μm\$) and RXTE (2-15 keV) or \textbackslash{}textit\{XMM-Newton\} (0.7-10 keV). A clear correlation between the X-ray and the IR variable emission is found during both epochs but with very different properties. In the first epoch, the near-IR variability leads the X-ray by \$ \textbackslash{}sim 130 \textbackslash{}, ms\$. This is the opposite of what is usually observed in similar systems. The correlation is more complex in the second epoch, with both anti-correlation and correlations at negative and positive lags. Frequency-resolved Fourier analysis allows us to identify two main components in the complex structure of the phase lags: the first component, characterised by a few seconds near-IR lag at low frequencies, is consistent with a combination of disc reprocessing and a magnetised hot flow; the second component is identified at high frequencies by a near-IR lag of \$\textbackslash{}approx\$0.7 s. Given the similarities of this second component with the well-known constant optical/near-IR jet lag observed in other black hole transients, we tentatively interpret this feature as a signature of a longer-than-usual jet lag. We discuss the possible implications of measuring such a long jet lag in a radio-quiet black hole transient.",

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author = "Alberto Ulgiati and Vincentelli, \{Federico Maria\} and Piergiorgio Casella and Alexandra Veledina and Thomas Maccarone and David Russell and Phil Uttley and Filippo Ambrosino and Baglio, \{Maria Cristina\} and Matteo Imbrogno and Andrea Melandri and Motta, \{Sara Elisa\} and Kiran O'Brien and Andrea Sanna and Tariq Shahbaz and Diego Altamirano and Rob Fender and Dipankar Maitra and Julien Malzac",

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doi = "10.1051/0004-6361/202450545",

language = "English",

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T1 - Fast X-ray/IR observations of the black hole transient Swift~J1753.5--0127

T2 - from an IR lead to a very long jet lag

AU - Ulgiati, Alberto

AU - Vincentelli, Federico Maria

AU - Casella, Piergiorgio

AU - Veledina, Alexandra

AU - Maccarone, Thomas

AU - Russell, David

AU - Uttley, Phil

AU - Ambrosino, Filippo

AU - Baglio, Maria Cristina

AU - Imbrogno, Matteo

AU - Melandri, Andrea

AU - Motta, Sara Elisa

AU - O'Brien, Kiran

AU - Sanna, Andrea

AU - Shahbaz, Tariq

AU - Altamirano, Diego

AU - Fender, Rob

AU - Maitra, Dipankar

AU - Malzac, Julien

PY - 2024/10/14

Y1 - 2024/10/14

N2 - We report on two epochs of simultaneous near-infrared (IR) and X-ray observations with a sub-second time resolution of the low mass X-ray binary black hole candidate Swift J1753.5--0127 during its long 2005--2016 outburst. Data were collected strictly simultaneously with VLT/ISAAC (K$_{S}$ band, 2.2 $μm$) and RXTE (2-15 keV) or \textit{XMM-Newton} (0.7-10 keV). A clear correlation between the X-ray and the IR variable emission is found during both epochs but with very different properties. In the first epoch, the near-IR variability leads the X-ray by $ \sim 130 \, ms$. This is the opposite of what is usually observed in similar systems. The correlation is more complex in the second epoch, with both anti-correlation and correlations at negative and positive lags. Frequency-resolved Fourier analysis allows us to identify two main components in the complex structure of the phase lags: the first component, characterised by a few seconds near-IR lag at low frequencies, is consistent with a combination of disc reprocessing and a magnetised hot flow; the second component is identified at high frequencies by a near-IR lag of $\approx$0.7 s. Given the similarities of this second component with the well-known constant optical/near-IR jet lag observed in other black hole transients, we tentatively interpret this feature as a signature of a longer-than-usual jet lag. We discuss the possible implications of measuring such a long jet lag in a radio-quiet black hole transient.

AB - We report on two epochs of simultaneous near-infrared (IR) and X-ray observations with a sub-second time resolution of the low mass X-ray binary black hole candidate Swift J1753.5--0127 during its long 2005--2016 outburst. Data were collected strictly simultaneously with VLT/ISAAC (K$_{S}$ band, 2.2 $μm$) and RXTE (2-15 keV) or \textit{XMM-Newton} (0.7-10 keV). A clear correlation between the X-ray and the IR variable emission is found during both epochs but with very different properties. In the first epoch, the near-IR variability leads the X-ray by $ \sim 130 \, ms$. This is the opposite of what is usually observed in similar systems. The correlation is more complex in the second epoch, with both anti-correlation and correlations at negative and positive lags. Frequency-resolved Fourier analysis allows us to identify two main components in the complex structure of the phase lags: the first component, characterised by a few seconds near-IR lag at low frequencies, is consistent with a combination of disc reprocessing and a magnetised hot flow; the second component is identified at high frequencies by a near-IR lag of $\approx$0.7 s. Given the similarities of this second component with the well-known constant optical/near-IR jet lag observed in other black hole transients, we tentatively interpret this feature as a signature of a longer-than-usual jet lag. We discuss the possible implications of measuring such a long jet lag in a radio-quiet black hole transient.

KW - Stars: activity

KW - Stars: black holes

KW - Stars: evolution

KW - Stars: jets

UR - https://www.scopus.com/pages/publications/85207801142

U2 - 10.1051/0004-6361/202450545

DO - 10.1051/0004-6361/202450545

M3 - Article

SN - 0004-6361

VL - 690

JO - Astronomy & Astrophysics

JF - Astronomy & Astrophysics

M1 - A239

ER -

Fast X-ray/IR observations of the black hole transient Swift~J1753.5--0127: from an IR lead to a very long jet lag

Abstract

Bibliographical note

Funding

Keywords

ASJC Scopus subject areas

Access to Document

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