LOFAR 144-MHz follow-up observations of GW170817

J. W. Broderick; T. W. Shimwell; K. Gourdji; A. Rowlinson; S. Nissanke; K. Hotokezaka; P. G. Jonker; C. Tasse; M. J. Hardcastle; J. B.R. Oonk; R. P. Fender; R. A.M.J. Wijers; A. Shulevski; A. J. Stewart; S. Ter Veen; V. A. Moss; M. H.D. Van Der Wiel; D. A. Nichols; A. Piette; M. E. Bell; D. Carbone; S. Corbel; J. Eislöffel; J. M. Grießmeier; E. F. Keane; C. J. Law; T. Muñoz-Darias; M. Pietka; M. Serylak; A. J. Van Der Horst; J. Van Leeuwen; R. Wijnands; P. Zarka; J. M. Anderson; M. J. Bentum; R. Blaauw; W. N. Brouw; M. Brüggen; B. Ciardi; M. De Vos; S. Duscha; R. A. Fallows; T. M.O. Franzen; M. A. Garrett; A. W. Gunst; M. Hoeft; J. R. Hörandel; M. Iacobelli; E. Jütte; L. V.E. Koopmans; A. Krankowski; P. Maat; G. Mann; H. Mulder; A. Nelles; H. Paas; M. Pandey-Pommier; R. Pekal; W. Reich; H. J.A. Röttgering; D. J. Schwarz; O. Smirnov; M. Soida; M. C. Toribio; M. P. Van Haarlem; R. J. Van Weeren; C. Vocks; O. Wucknitz; P. Zucca

doi:10.1093/mnras/staa950

LOFAR 144-MHz follow-up observations of GW170817

J. W. Broderick
, T. W. Shimwell
, K. Gourdji
, A. Rowlinson
, S. Nissanke
, K. Hotokezaka
, P. G. Jonker
, C. Tasse
, M. J. Hardcastle
, J. B.R. Oonk
, R. P. Fender
, R. A.M.J. Wijers
, A. Shulevski
, A. J. Stewart
, S. Ter Veen
, V. A. Moss
, M. H.D. Van Der Wiel
, D. A. Nichols
, A. Piette
, M. E. Bell

D. Carbone, S. Corbel, J. Eislöffel, J. M. Grießmeier, E. F. Keane, C. J. Law, T. Muñoz-Darias, M. Pietka, M. Serylak, A. J. Van Der Horst, J. Van Leeuwen, R. Wijnands, P. Zarka, J. M. Anderson, M. J. Bentum, R. Blaauw, W. N. Brouw, M. Brüggen, B. Ciardi, M. De Vos, S. Duscha, R. A. Fallows, T. M.O. Franzen, M. A. Garrett, A. W. Gunst, M. Hoeft, J. R. Hörandel, M. Iacobelli, E. Jütte, L. V.E. Koopmans, A. Krankowski, P. Maat, G. Mann, H. Mulder, A. Nelles, H. Paas, M. Pandey-Pommier, R. Pekal, W. Reich, H. J.A. Röttgering, D. J. Schwarz, O. Smirnov, M. Soida, M. C. Toribio, M. P. Van Haarlem, R. J. Van Weeren, C. Vocks, O. Wucknitz, P. Zucca

Netherlands Institute for Radio Astronomy
Curtin University
Leiden University
University of Amsterdam
Nikhef
Princeton University
Research Center for the Early Universe
SRON Netherlands Institute for Space Research
Radboud University
Université PSL
Rhodes University
University of Hertfordshire
SURFsara, Netherlands
University of Oxford
Sydney University Biological Informatics and Technology Centre (SUBIT)
Commonwealth Scientific Industrial and Research Organization
University of Virginia
Institute of Astronomy
University of Technology Sydney
University of the Virgin Islands
CEA Saclay
PSL Research University
Thüringer Landessternwarte Tautenburg
Université d'Orléans
University of Manchester
California Institute of Technology
GTC Project
Universidad de la Laguna
South African Radio Astronomy Observatory
University of the Western Cape
George Washington University
LESIA - Laboratoire d'Etudes Spatiales et d'Instrumentation en Astrophysique
FR6-10
GeoForshungsZentrum-Potsdam
Eindhoven University of Technology
University of Groningen
University of Hamburg
Max Planck Institute for Astrophysics
Vrije Universiteit Brussel
Ruhr-Universität Bochum
University of Varmia and Masuria
Astrophysikalisches Institut Potsdam
DESY
University of Erlangen-Nuremberg
University of Groningen
Université de Lyon
Poznan Supercomputing and Networking Center (PSNC)
Max-Planck-Institut für Radioastronomie
Bielefeld University
Uniwersytet Jagielloński
Onsala Space Observatory

Research output: Contribution to a Journal (Peer & Non Peer) › Article › peer-review

15 Citations (Scopus)

Abstract

We present low-radio-frequency follow-up observations of AT 2017gfo, the electromagnetic counterpart of GW170817, which was the first binary neutron star merger to be detected by Advanced LIGO-Virgo. These data, with a central frequency of 144 MHz, were obtained with LOFAR, the Low-Frequency Array. The maximum elevation of the target is just 13.7 when observed with LOFAR, making our observations particularly challenging to calibrate and significantly limiting the achievable sensitivity. On time-scales of 130-138 and 371-374 d after the merger event, we obtain 3σ upper limits for the afterglow component of 6.6 and 19.5 mJy beam-1, respectively. Using our best upper limit and previously published, contemporaneous higher frequency radio data, we place a limit on any potential steepening of the radio spectrum between 610 and 144 MHz: The two-point spectral index α 610 144 gtrsim -2.5. We also show that LOFAR can detect the afterglows of future binary neutron star merger events occurring at more favourable elevations.

Original language	English
Pages (from-to)	5110-5117
Number of pages	8
Journal	Monthly Notices of the Royal Astronomical Society
Volume	494
Issue number	4
DOIs	https://doi.org/10.1093/mnras/staa950
Publication status	Published - 1 Jun 2020
Externally published	Yes

Keywords

gravitational waves
radio continuum: Stars
stars: Neutron

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10.1093/mnras/staa950

Cite this

Broderick, J. W., Shimwell, T. W., Gourdji, K., Rowlinson, A., Nissanke, S., Hotokezaka, K., Jonker, P. G., Tasse, C., Hardcastle, M. J., Oonk, J. B. R., Fender, R. P., Wijers, R. A. M. J., Shulevski, A., Stewart, A. J., Ter Veen, S., Moss, V. A., Van Der Wiel, M. H. D., Nichols, D. A., Piette, A., ... Zucca, P. (2020). LOFAR 144-MHz follow-up observations of GW170817. Monthly Notices of the Royal Astronomical Society, 494(4), 5110-5117. https://doi.org/10.1093/mnras/staa950

@article{d8794b9c14e14a9caf00a641f2a1e22a,

title = "LOFAR 144-MHz follow-up observations of GW170817",

abstract = "We present low-radio-frequency follow-up observations of AT 2017gfo, the electromagnetic counterpart of GW170817, which was the first binary neutron star merger to be detected by Advanced LIGO-Virgo. These data, with a central frequency of 144 MHz, were obtained with LOFAR, the Low-Frequency Array. The maximum elevation of the target is just 13.7 when observed with LOFAR, making our observations particularly challenging to calibrate and significantly limiting the achievable sensitivity. On time-scales of 130-138 and 371-374 d after the merger event, we obtain 3σ upper limits for the afterglow component of 6.6 and 19.5 mJy beam-1, respectively. Using our best upper limit and previously published, contemporaneous higher frequency radio data, we place a limit on any potential steepening of the radio spectrum between 610 and 144 MHz: The two-point spectral index α 610 144 gtrsim -2.5. We also show that LOFAR can detect the afterglows of future binary neutron star merger events occurring at more favourable elevations.",

keywords = "gravitational waves, radio continuum: Stars, stars: Neutron",

author = "Broderick, \{J. W.\} and Shimwell, \{T. W.\} and K. Gourdji and A. Rowlinson and S. Nissanke and K. Hotokezaka and Jonker, \{P. G.\} and C. Tasse and Hardcastle, \{M. J.\} and Oonk, \{J. B.R.\} and Fender, \{R. P.\} and Wijers, \{R. A.M.J.\} and A. Shulevski and Stewart, \{A. J.\} and \{Ter Veen\}, S. and Moss, \{V. A.\} and \{Van Der Wiel\}, \{M. H.D.\} and Nichols, \{D. A.\} and A. Piette and Bell, \{M. E.\} and D. Carbone and S. Corbel and J. Eisl{\"o}ffel and Grie{\ss}meier, \{J. M.\} and Keane, \{E. F.\} and Law, \{C. J.\} and T. Mu{\~n}oz-Darias and M. Pietka and M. Serylak and \{Van Der Horst\}, \{A. J.\} and \{Van Leeuwen\}, J. and R. Wijnands and P. Zarka and Anderson, \{J. M.\} and Bentum, \{M. J.\} and R. Blaauw and Brouw, \{W. N.\} and M. Br{\"u}ggen and B. Ciardi and \{De Vos\}, M. and S. Duscha and Fallows, \{R. A.\} and Franzen, \{T. M.O.\} and Garrett, \{M. A.\} and Gunst, \{A. W.\} and M. Hoeft and H{\"o}randel, \{J. R.\} and M. Iacobelli and E. J{\"u}tte and Koopmans, \{L. V.E.\} and A. Krankowski and P. Maat and G. Mann and H. Mulder and A. Nelles and H. Paas and M. Pandey-Pommier and R. Pekal and W. Reich and R{\"o}ttgering, \{H. J.A.\} and Schwarz, \{D. J.\} and O. Smirnov and M. Soida and Toribio, \{M. C.\} and \{Van Haarlem\}, \{M. P.\} and \{Van Weeren\}, \{R. J.\} and C. Vocks and O. Wucknitz and P. Zucca",

note = "Publisher Copyright: {\textcopyright} 2020 The Author(s).",

year = "2020",

month = jun,

day = "1",

doi = "10.1093/mnras/staa950",

language = "English",

volume = "494",

pages = "5110--5117",

journal = "Monthly Notices of the Royal Astronomical Society",

issn = "0035-8711",

publisher = "Oxford University Press",

number = "4",

}

Broderick, JW, Shimwell, TW, Gourdji, K, Rowlinson, A, Nissanke, S, Hotokezaka, K, Jonker, PG, Tasse, C, Hardcastle, MJ, Oonk, JBR, Fender, RP, Wijers, RAMJ, Shulevski, A, Stewart, AJ, Ter Veen, S, Moss, VA, Van Der Wiel, MHD, Nichols, DA, Piette, A, Bell, ME, Carbone, D, Corbel, S, Eislöffel, J, Grießmeier, JM, Keane, EF, Law, CJ, Muñoz-Darias, T, Pietka, M, Serylak, M, Van Der Horst, AJ, Van Leeuwen, J, Wijnands, R, Zarka, P, Anderson, JM, Bentum, MJ, Blaauw, R, Brouw, WN, Brüggen, M, Ciardi, B, De Vos, M, Duscha, S, Fallows, RA, Franzen, TMO, Garrett, MA, Gunst, AW, Hoeft, M, Hörandel, JR, Iacobelli, M, Jütte, E, Koopmans, LVE, Krankowski, A, Maat, P, Mann, G, Mulder, H, Nelles, A, Paas, H, Pandey-Pommier, M, Pekal, R, Reich, W, Röttgering, HJA, Schwarz, DJ, Smirnov, O, Soida, M, Toribio, MC, Van Haarlem, MP, Van Weeren, RJ, Vocks, C, Wucknitz, O & Zucca, P 2020, 'LOFAR 144-MHz follow-up observations of GW170817', Monthly Notices of the Royal Astronomical Society, vol. 494, no. 4, pp. 5110-5117. https://doi.org/10.1093/mnras/staa950

TY - JOUR

T1 - LOFAR 144-MHz follow-up observations of GW170817

AU - Broderick, J. W.

AU - Shimwell, T. W.

AU - Gourdji, K.

AU - Rowlinson, A.

AU - Nissanke, S.

AU - Hotokezaka, K.

AU - Jonker, P. G.

AU - Tasse, C.

AU - Hardcastle, M. J.

AU - Oonk, J. B.R.

AU - Fender, R. P.

AU - Wijers, R. A.M.J.

AU - Shulevski, A.

AU - Stewart, A. J.

AU - Ter Veen, S.

AU - Moss, V. A.

AU - Van Der Wiel, M. H.D.

AU - Nichols, D. A.

AU - Piette, A.

AU - Bell, M. E.

AU - Carbone, D.

AU - Corbel, S.

AU - Eislöffel, J.

AU - Grießmeier, J. M.

AU - Keane, E. F.

AU - Law, C. J.

AU - Muñoz-Darias, T.

AU - Pietka, M.

AU - Serylak, M.

AU - Van Der Horst, A. J.

AU - Van Leeuwen, J.

AU - Wijnands, R.

AU - Zarka, P.

AU - Anderson, J. M.

AU - Bentum, M. J.

AU - Blaauw, R.

AU - Brouw, W. N.

AU - Brüggen, M.

AU - Ciardi, B.

AU - De Vos, M.

AU - Duscha, S.

AU - Fallows, R. A.

AU - Franzen, T. M.O.

AU - Garrett, M. A.

AU - Gunst, A. W.

AU - Hoeft, M.

AU - Hörandel, J. R.

AU - Iacobelli, M.

AU - Jütte, E.

AU - Koopmans, L. V.E.

AU - Krankowski, A.

AU - Maat, P.

AU - Mann, G.

AU - Mulder, H.

AU - Nelles, A.

AU - Paas, H.

AU - Pandey-Pommier, M.

AU - Pekal, R.

AU - Reich, W.

AU - Röttgering, H. J.A.

AU - Schwarz, D. J.

AU - Smirnov, O.

AU - Soida, M.

AU - Toribio, M. C.

AU - Van Haarlem, M. P.

AU - Van Weeren, R. J.

AU - Vocks, C.

AU - Wucknitz, O.

AU - Zucca, P.

PY - 2020/6/1

Y1 - 2020/6/1

N2 - We present low-radio-frequency follow-up observations of AT 2017gfo, the electromagnetic counterpart of GW170817, which was the first binary neutron star merger to be detected by Advanced LIGO-Virgo. These data, with a central frequency of 144 MHz, were obtained with LOFAR, the Low-Frequency Array. The maximum elevation of the target is just 13.7 when observed with LOFAR, making our observations particularly challenging to calibrate and significantly limiting the achievable sensitivity. On time-scales of 130-138 and 371-374 d after the merger event, we obtain 3σ upper limits for the afterglow component of 6.6 and 19.5 mJy beam-1, respectively. Using our best upper limit and previously published, contemporaneous higher frequency radio data, we place a limit on any potential steepening of the radio spectrum between 610 and 144 MHz: The two-point spectral index α 610 144 gtrsim -2.5. We also show that LOFAR can detect the afterglows of future binary neutron star merger events occurring at more favourable elevations.

AB - We present low-radio-frequency follow-up observations of AT 2017gfo, the electromagnetic counterpart of GW170817, which was the first binary neutron star merger to be detected by Advanced LIGO-Virgo. These data, with a central frequency of 144 MHz, were obtained with LOFAR, the Low-Frequency Array. The maximum elevation of the target is just 13.7 when observed with LOFAR, making our observations particularly challenging to calibrate and significantly limiting the achievable sensitivity. On time-scales of 130-138 and 371-374 d after the merger event, we obtain 3σ upper limits for the afterglow component of 6.6 and 19.5 mJy beam-1, respectively. Using our best upper limit and previously published, contemporaneous higher frequency radio data, we place a limit on any potential steepening of the radio spectrum between 610 and 144 MHz: The two-point spectral index α 610 144 gtrsim -2.5. We also show that LOFAR can detect the afterglows of future binary neutron star merger events occurring at more favourable elevations.

KW - gravitational waves

KW - radio continuum: Stars

KW - stars: Neutron

UR - https://www.scopus.com/pages/publications/85095324737

U2 - 10.1093/mnras/staa950

DO - 10.1093/mnras/staa950

M3 - Article

SN - 0035-8711

VL - 494

SP - 5110

EP - 5117

JO - Monthly Notices of the Royal Astronomical Society

JF - Monthly Notices of the Royal Astronomical Society

IS - 4

ER -

LOFAR 144-MHz follow-up observations of GW170817

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Keywords

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