CaltechAUTHORS
Published May 16, 2019 | Accepted Version + Supplemental Material
Journal Article Open

A rapidly changing jet orientation in the stellar-mass black-hole system V404 Cygni

Miller-Jones, James C. A. ORCID icon
Tetarenko, Alexandra J. ORCID icon
Sivakoff, Gregory R. ORCID icon
Middleton, Matthew J. ORCID icon
Altamirano, Diego ORCID icon
Anderson, Gemma E.
Belloni, Tomaso M.
Fender, Rob P.
Jonker, Peter G. ORCID icon
Körding, Elmar G.
Krimm, Hans A. ORCID icon
Maitra, Dipankar
Markoff, Sera ORCID icon
Migliari, Simone
Mooley, Kunal P. ORCID icon
Rupen, Michael P.
Russell, David M. ORCID icon
Russell, Thomas D. ORCID icon
Sarazin, Craig L.
Soria, Roberto ORCID icon
Tudose, Valeriu
An error occurred while generating the citation.

Abstract

Powerful relativistic jets are one of the main ways in which accreting black holes provide kinetic feedback to their surroundings. Jets launched from or redirected by the accretion flow that powers them are expected to be affected by the dynamics of the flow, which for accreting stellar-mass black holes has shown evidence for precession due to frame-dragging effects that occur when the black-hole spin axis is misaligned with the orbital plane of its companion star. Recently, theoretical simulations have suggested that the jets can exert an additional torque on the accretion flow, although the interplay between the dynamics of the accretion flow and the launching of the jets is not yet understood. Here we report a rapidly changing jet orientation—on a time scale of minutes to hours—in the black-hole X-ray binary V404 Cygni, detected with very-long-baseline interferometry during the peak of its 2015 outburst. We show that this changing jet orientation can be modelled as the Lense–Thirring precession of a vertically extended slim disk that arises from the super-Eddington accretion rate. Our findings suggest that the dynamics of the precessing inner accretion disk could play a role in either directly launching or redirecting the jets within the inner few hundred gravitational radii. Similar dynamics should be expected in any strongly accreting black hole whose spin is misaligned with the inflowing gas, both affecting the observational characteristics of the jets and distributing the black-hole feedback more uniformly over the surrounding environment.

Additional Information

© 2019 Springer Nature Publishing AG. Received 29 August 2018; Accepted 06 February 2019; Published 29 April 2019. Data availability: The raw VLBA data are publicly available from the NRAO archive (https://archive.nrao.edu/archive/advquery.jsp), under project codes BM421 and BS249. All software packages used in our analysis (AIPS, Difmap, CASA, UVMULTIFIT and EMCEE) are publicly available. The final calibrated images and uv-data are available from the corresponding author upon reasonable request. The data underlying the figures are available as csv or xlsx files, and the measured positions and flux densities of all VLBA components from 22 June 2015 are included with the MCMC fitting code (see below). Code availability: The MCMC fitting code is available at https://github.com/tetarenk/jet-jitter. The National Radio Astronomy Observatory is a facility of the National Science Foundation operated under cooperative agreement by Associated Universities, Inc. J.C.A.M.-J. is the recipient of an Australian Research Council Future Fellowship (FT140101082) funded by the Australian Government. A.J.T. is supported by a Natural Sciences and Engineering Research Council of Canada (NSERC) Post-Graduate Doctoral Scholarship (PGSD2-490318-2016). A.J.T. and G.R.S. acknowledge support from NSERC Discovery Grants (RGPIN-402752-2011 and RGPIN-06569-2016). M.J.M. acknowledges support from a Science and Technology Facilities Council (STFC) Ernest Rutherford Fellowship. D.A. acknowledges support from the Royal Society. G.E.A. is the recipient of an Australian Research Council Discovery Early Career Researcher Award (project number DE180100346) funded by the Australian Government. T.M.B. acknowledges a financial contribution from the agreement ASI-INAF n.2017-14-H.0. P.G.J. acknowledges funding from the European Research Council under ERC Consolidator Grant agreement 647208. S. Markoff and T.D.R. acknowledge support from a Netherlands Organisation for Scientific Research (NWO) Veni Fellowship and Vici Grant, respectively. K.P.M. acknowledges support from the Oxford Centre for Astrophysical Surveys, which is funded through the Hintze Family Charitable Foundation. K.P.M. is currently a Jansky Fellow of the National Radio Astronomy Observatory. This work profited from discussions carried out during a meeting on multi-wavelength rapid variability organized at the International Space Science Institute (ISSI) Beijing by T.M.B. and D. Bhattacharya. The authors acknowledge the worldwide effort in observing this outburst, and the planning tools (created by T. Marsh and coordinated by C. Knigge) that enabled these observations. Author Contributions: J.C.A.M.-J. wrote the manuscript with input from all authors. J.C.A.M.-J. wrote the observing proposal BM421 with help from all authors. G.R.S. wrote the observing proposal BS249 with help from J.C.A.M.-.J., A.J.T., R.P.F., P.G.J., G.E.A. and K.P.M. J.C.A.M.-J. designed and processed the VLBA observations. A.J.T. performed the Monte Carlo modelling. J.C.A.M.-J., A.J.T. and G.R.S. analysed the data. M.J.M. led the development of the Lense–Thirring precession scenario, with help from S. Markoff. The authors declare no competing interests.

Attached Files

Accepted Version - 1906.05400.pdf

Supplemental Material - 41586_2019_1152_Fig5_ESM.jpg

Supplemental Material - 41586_2019_1152_Fig6_ESM.jpg

Supplemental Material - 41586_2019_1152_Fig7_ESM.jpg

Supplemental Material - 41586_2019_1152_Fig8_ESM.jpg

Supplemental Material - 41586_2019_1152_Fig9_ESM.jpg

Supplemental Material - 41586_2019_1152_MOESM1_ESM.mp4

Supplemental Material - 41586_2019_1152_MOESM2_ESM.xlsx

Supplemental Material - 41586_2019_1152_MOESM3_ESM.csv

Supplemental Material - 41586_2019_1152_MOESM4_ESM.csv

Supplemental Material - 41586_2019_1152_MOESM5_ESM.xlsx

Supplemental Material - 41586_2019_1152_MOESM6_ESM.csv

Supplemental Material - 41586_2019_1152_MOESM7_ESM.csv

Supplemental Material - 41586_2019_1152_MOESM8_ESM.csv

Supplemental Material - 41586_2019_1152_MOESM9_ESM.csv

Supplemental Material - 41586_2019_1152_Tab1_ESM.jpg

Supplemental Material - 41586_2019_1152_Tab2_ESM.jpg

Supplemental Material - 41586_2019_1152_Tab3_ESM.jpg

Supplemental Material - 41586_2019_1152_Tab4_ESM.jpg

Supplemental Material - 41586_2019_1152_Tab5_ESM.jpg

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Additional details

Identifiers Related works Funding Dates
Created:
August 22, 2023
Modified:
October 20, 2023