Observing pulsars and fast transients with LOFAR

B. W. Stappers; J. W. T. Hessels; A. Alexov; K. Anderson; T. Coenen; T. Hassall; A. Karastergiou; V. I. Kondratiev; M. Kramer; J. van Leeuwen; J.D. Mol; A. Noutsos; J. W. Romein; P. Weltevrede; R. Fender; R. A. M. J. Wijers; L. Bahren; M. E. Bell; J. Broderick; E. J. Daw; V. S. Dhillon; J. Eisloeffel; H. Falcke; J. Griessmeier; C. Law; S. Markoff; J. C. A. Miller-Jones; B. Scheers; H. Spreeuw; J. Swinbank; S. ter Veen; M. W. Wise; O. Wucknitz; P. Zarka; J. Anderson; A. Asgekar; I. M. Avruch; R. Beck; P. Bennema; M. J. Bentum; P. Best; J. Bregman; M. Brentjens; R. H. van de Brink; P.C. Broekema; W. N. Brouw; M. Brueggen; A. G. de Bruyn; H. R. Butcher; B. Ciardi; J. Conway; R. -J. Dettmar; A. van Duin; J. van Enst; M. Garrett; M. Gerbers; T. Grit; A. Gunst; M.P. van Haarlem; J. P. Hamaker; G. Heald; M. Hoeft; H. Holties; A. Horneffer; L. V. E. Koopmans; G. Kuper; M. Loose; P. Maat; D. McKay-Bukowski; J. P. McKean; G. Miley; R. Morganti; R. Nijboer; J. E. Noordam; M. Norden; H. Olofsson; M. Pandey-Pommier; A. Polatidis; W. Reich; H. Rottgering; A. Schoenmakers; J. Sluman; O. Smirnov; M. Steinmetz; C.G.M. Sterks; M. Tagger; Y. Tang; R. Vermeulen; N. Vermaas; C. Vogt; M. de Vos; S. J. Wijnholds; S. Yatawatta; A. Zensus

doi:10.1051/0004-6361/201116681

Observing pulsars and fast transients with LOFAR

B. W. Stappers^*
, J. W. T. Hessels
, A. Alexov
, K. Anderson
, T. Coenen
, T. Hassall
, A. Karastergiou
, V. I. Kondratiev
, M. Kramer
, J. van Leeuwen
, J.D. Mol
, A. Noutsos
, J. W. Romein
, P. Weltevrede
, R. Fender
, R. A. M. J. Wijers
, L. Bahren
, M. E. Bell
, J. Broderick
, E. J. Daw

V. S. Dhillon, J. Eisloeffel, H. Falcke, J. Griessmeier, C. Law, S. Markoff, J. C. A. Miller-Jones, B. Scheers, H. Spreeuw, J. Swinbank, S. ter Veen, M. W. Wise, O. Wucknitz, P. Zarka, J. Anderson, A. Asgekar, I. M. Avruch, R. Beck, P. Bennema, M. J. Bentum, P. Best, J. Bregman, M. Brentjens, R. H. van de Brink, P.C. Broekema, W. N. Brouw, M. Brueggen, A. G. de Bruyn, H. R. Butcher, B. Ciardi, J. Conway, R. -J. Dettmar, A. van Duin, J. van Enst, M. Garrett, M. Gerbers, T. Grit, A. Gunst, M.P. van Haarlem, J. P. Hamaker, G. Heald, M. Hoeft, H. Holties, A. Horneffer, L. V. E. Koopmans, G. Kuper, M. Loose, P. Maat, D. McKay-Bukowski, J. P. McKean, G. Miley, R. Morganti, R. Nijboer, J. E. Noordam, M. Norden, H. Olofsson, M. Pandey-Pommier, A. Polatidis, W. Reich, H. Rottgering, A. Schoenmakers, J. Sluman, O. Smirnov, M. Steinmetz, C.G.M. Sterks, M. Tagger, Y. Tang, R. Vermeulen, N. Vermaas, C. Vogt, M. de Vos, S. J. Wijnholds, S. Yatawatta, A. Zensus

^*Corresponding author for this work

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

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Abstract

Low frequency radio waves, while challenging to observe, are a rich source of information about pulsars. The LOw Frequency ARray (LOFAR) is a new radio interferometer operating in the lowest 4 octaves of the ionospheric "radio window": 10-240 MHz, that will greatly facilitate observing pulsars at low radio frequencies. Through the huge collecting area, long baselines, and flexible digital hardware, it is expected that LOFAR will revolutionize radio astronomy at the lowest frequencies visible from Earth. LOFAR is a next-generation radio telescope and a pathfinder to the Square Kilometre Array (SKA), in that it incorporates advanced multi-beaming techniques between thousands of individual elements. We discuss the motivation for low-frequency pulsar observations in general and the potential of LOFAR in addressing these science goals. We present LOFAR as it is designed to perform high-time-resolution observations of pulsars and other fast transients, and outline the various relevant observing modes and data reduction pipelines that are already or will soon be implemented to facilitate these observations. A number of results obtained from commissioning observations are presented to demonstrate the exciting potential of the telescope. This paper outlines the case for low frequency pulsar observations and is also intended to serve as a reference for upcoming pulsar/fast transient science papers with LOFAR.

Original language	English
Article number	A80
Number of pages	32
Journal	Astronomy & Astrophysics
Volume	530
DOIs	https://doi.org/10.1051/0004-6361/201116681
Publication status	Published - Jun-2011

Keywords

telescopes
pulsars: general
instrumentation: interferometers
methods: observational
stars: neutron
ISM: general
BINARY MILLISECOND PULSAR
RADIO-CONTINUUM EMISSION
DENSITY POWER SPECTRUM
GAMMA-RAY PULSARS
LOW-FREQUENCY
INTERSTELLAR PLASMA
FLUX DENSITIES
NEUTRON-STARS
DECAMETER WAVELENGTHS
INTENSITY VARIATIONS

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Stappers, B. W., Hessels, J. W. T., Alexov, A., Anderson, K., Coenen, T., Hassall, T., Karastergiou, A., Kondratiev, V. I., Kramer, M., van Leeuwen, J., Mol, J. D., Noutsos, A., Romein, J. W., Weltevrede, P., Fender, R., Wijers, R. A. M. J., Bahren, L., Bell, M. E., Broderick, J., ... Zensus, A. (2011). Observing pulsars and fast transients with LOFAR. Astronomy & Astrophysics, 530, Article A80. https://doi.org/10.1051/0004-6361/201116681

@article{619e0ba70fef406c9761b2b0fcd9c69b,

title = "Observing pulsars and fast transients with LOFAR",

abstract = "Low frequency radio waves, while challenging to observe, are a rich source of information about pulsars. The LOw Frequency ARray (LOFAR) is a new radio interferometer operating in the lowest 4 octaves of the ionospheric {"}radio window{"}: 10-240 MHz, that will greatly facilitate observing pulsars at low radio frequencies. Through the huge collecting area, long baselines, and flexible digital hardware, it is expected that LOFAR will revolutionize radio astronomy at the lowest frequencies visible from Earth. LOFAR is a next-generation radio telescope and a pathfinder to the Square Kilometre Array (SKA), in that it incorporates advanced multi-beaming techniques between thousands of individual elements. We discuss the motivation for low-frequency pulsar observations in general and the potential of LOFAR in addressing these science goals. We present LOFAR as it is designed to perform high-time-resolution observations of pulsars and other fast transients, and outline the various relevant observing modes and data reduction pipelines that are already or will soon be implemented to facilitate these observations. A number of results obtained from commissioning observations are presented to demonstrate the exciting potential of the telescope. This paper outlines the case for low frequency pulsar observations and is also intended to serve as a reference for upcoming pulsar/fast transient science papers with LOFAR.",

keywords = "telescopes, pulsars: general, instrumentation: interferometers, methods: observational, stars: neutron, ISM: general, BINARY MILLISECOND PULSAR, RADIO-CONTINUUM EMISSION, DENSITY POWER SPECTRUM, GAMMA-RAY PULSARS, LOW-FREQUENCY, INTERSTELLAR PLASMA, FLUX DENSITIES, NEUTRON-STARS, DECAMETER WAVELENGTHS, INTENSITY VARIATIONS",

author = "Stappers, \{B. W.\} and Hessels, \{J. W. T.\} and A. Alexov and K. Anderson and T. Coenen and T. Hassall and A. Karastergiou and Kondratiev, \{V. I.\} and M. Kramer and \{van Leeuwen\}, J. and J.D. Mol and A. Noutsos and Romein, \{J. W.\} and P. Weltevrede and R. Fender and Wijers, \{R. A. M. J.\} and L. Bahren and Bell, \{M. E.\} and J. Broderick and Daw, \{E. J.\} and Dhillon, \{V. S.\} and J. Eisloeffel and H. Falcke and J. Griessmeier and C. Law and S. Markoff and Miller-Jones, \{J. C. A.\} and B. Scheers and H. Spreeuw and J. Swinbank and \{ter Veen\}, S. and Wise, \{M. W.\} and O. Wucknitz and P. Zarka and J. Anderson and A. Asgekar and Avruch, \{I. M.\} and R. Beck and P. Bennema and Bentum, \{M. J.\} and P. Best and J. Bregman and M. Brentjens and \{van de Brink\}, \{R. H.\} and P.C. Broekema and Brouw, \{W. N.\} and M. Brueggen and \{de Bruyn\}, \{A. G.\} and Butcher, \{H. R.\} and B. Ciardi and J. Conway and Dettmar, \{R. -J.\} and \{van Duin\}, A. and \{van Enst\}, J. and M. Garrett and M. Gerbers and T. Grit and A. Gunst and \{van Haarlem\}, M.P. and Hamaker, \{J. P.\} and G. Heald and M. Hoeft and H. Holties and A. Horneffer and Koopmans, \{L. V. E.\} and G. Kuper and M. Loose and P. Maat and D. McKay-Bukowski and McKean, \{J. P.\} and G. Miley and R. Morganti and R. Nijboer and Noordam, \{J. E.\} and M. Norden and H. Olofsson and M. Pandey-Pommier and A. Polatidis and W. Reich and H. Rottgering and A. Schoenmakers and J. Sluman and O. Smirnov and M. Steinmetz and C.G.M. Sterks and M. Tagger and Y. Tang and R. Vermeulen and N. Vermaas and C. Vogt and \{de Vos\}, M. and Wijnholds, \{S. J.\} and S. Yatawatta and A. Zensus",

year = "2011",

month = jun,

doi = "10.1051/0004-6361/201116681",

language = "English",

volume = "530",

journal = "Astronomy \& Astrophysics",

issn = "0004-6361",

publisher = " EDP Sciences",

}

Stappers, BW, Hessels, JWT, Alexov, A, Anderson, K, Coenen, T, Hassall, T, Karastergiou, A, Kondratiev, VI, Kramer, M, van Leeuwen, J, Mol, JD, Noutsos, A, Romein, JW, Weltevrede, P, Fender, R, Wijers, RAMJ, Bahren, L, Bell, ME, Broderick, J, Daw, EJ, Dhillon, VS, Eisloeffel, J, Falcke, H, Griessmeier, J, Law, C, Markoff, S, Miller-Jones, JCA, Scheers, B, Spreeuw, H, Swinbank, J, ter Veen, S, Wise, MW, Wucknitz, O, Zarka, P, Anderson, J, Asgekar, A, Avruch, IM, Beck, R, Bennema, P, Bentum, MJ, Best, P, Bregman, J, Brentjens, M, van de Brink, RH, Broekema, PC, Brouw, WN, Brueggen, M, de Bruyn, AG, Butcher, HR, Ciardi, B, Conway, J, Dettmar, R-J, van Duin, A, van Enst, J, Garrett, M, Gerbers, M, Grit, T, Gunst, A, van Haarlem, MP, Hamaker, JP, Heald, G, Hoeft, M, Holties, H, Horneffer, A, Koopmans, LVE, Kuper, G, Loose, M, Maat, P, McKay-Bukowski, D, McKean, JP, Miley, G, Morganti, R, Nijboer, R, Noordam, JE, Norden, M, Olofsson, H, Pandey-Pommier, M, Polatidis, A, Reich, W, Rottgering, H, Schoenmakers, A, Sluman, J, Smirnov, O, Steinmetz, M, Sterks, CGM, Tagger, M, Tang, Y, Vermeulen, R, Vermaas, N, Vogt, C, de Vos, M, Wijnholds, SJ, Yatawatta, S & Zensus, A 2011, 'Observing pulsars and fast transients with LOFAR', Astronomy & Astrophysics, vol. 530, A80. https://doi.org/10.1051/0004-6361/201116681

TY - JOUR

T1 - Observing pulsars and fast transients with LOFAR

AU - Stappers, B. W.

AU - Hessels, J. W. T.

AU - Alexov, A.

AU - Anderson, K.

AU - Coenen, T.

AU - Hassall, T.

AU - Karastergiou, A.

AU - Kondratiev, V. I.

AU - Kramer, M.

AU - van Leeuwen, J.

AU - Mol, J.D.

AU - Noutsos, A.

AU - Romein, J. W.

AU - Weltevrede, P.

AU - Fender, R.

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

AU - Bahren, L.

AU - Bell, M. E.

AU - Broderick, J.

AU - Daw, E. J.

AU - Dhillon, V. S.

AU - Eisloeffel, J.

AU - Falcke, H.

AU - Griessmeier, J.

AU - Law, C.

AU - Markoff, S.

AU - Miller-Jones, J. C. A.

AU - Scheers, B.

AU - Spreeuw, H.

AU - Swinbank, J.

AU - ter Veen, S.

AU - Wise, M. W.

AU - Wucknitz, O.

AU - Zarka, P.

AU - Anderson, J.

AU - Asgekar, A.

AU - Avruch, I. M.

AU - Beck, R.

AU - Bennema, P.

AU - Bentum, M. J.

AU - Best, P.

AU - Bregman, J.

AU - Brentjens, M.

AU - van de Brink, R. H.

AU - Broekema, P.C.

AU - Brouw, W. N.

AU - Brueggen, M.

AU - de Bruyn, A. G.

AU - Butcher, H. R.

AU - Ciardi, B.

AU - Conway, J.

AU - Dettmar, R. -J.

AU - van Duin, A.

AU - van Enst, J.

AU - Garrett, M.

AU - Gerbers, M.

AU - Grit, T.

AU - Gunst, A.

AU - van Haarlem, M.P.

AU - Hamaker, J. P.

AU - Heald, G.

AU - Hoeft, M.

AU - Holties, H.

AU - Horneffer, A.

AU - Koopmans, L. V. E.

AU - Kuper, G.

AU - Loose, M.

AU - Maat, P.

AU - McKay-Bukowski, D.

AU - McKean, J. P.

AU - Miley, G.

AU - Morganti, R.

AU - Nijboer, R.

AU - Noordam, J. E.

AU - Norden, M.

AU - Olofsson, H.

AU - Pandey-Pommier, M.

AU - Polatidis, A.

AU - Reich, W.

AU - Rottgering, H.

AU - Schoenmakers, A.

AU - Sluman, J.

AU - Smirnov, O.

AU - Steinmetz, M.

AU - Sterks, C.G.M.

AU - Tagger, M.

AU - Tang, Y.

AU - Vermeulen, R.

AU - Vermaas, N.

AU - Vogt, C.

AU - de Vos, M.

AU - Wijnholds, S. J.

AU - Yatawatta, S.

AU - Zensus, A.

PY - 2011/6

Y1 - 2011/6

N2 - Low frequency radio waves, while challenging to observe, are a rich source of information about pulsars. The LOw Frequency ARray (LOFAR) is a new radio interferometer operating in the lowest 4 octaves of the ionospheric "radio window": 10-240 MHz, that will greatly facilitate observing pulsars at low radio frequencies. Through the huge collecting area, long baselines, and flexible digital hardware, it is expected that LOFAR will revolutionize radio astronomy at the lowest frequencies visible from Earth. LOFAR is a next-generation radio telescope and a pathfinder to the Square Kilometre Array (SKA), in that it incorporates advanced multi-beaming techniques between thousands of individual elements. We discuss the motivation for low-frequency pulsar observations in general and the potential of LOFAR in addressing these science goals. We present LOFAR as it is designed to perform high-time-resolution observations of pulsars and other fast transients, and outline the various relevant observing modes and data reduction pipelines that are already or will soon be implemented to facilitate these observations. A number of results obtained from commissioning observations are presented to demonstrate the exciting potential of the telescope. This paper outlines the case for low frequency pulsar observations and is also intended to serve as a reference for upcoming pulsar/fast transient science papers with LOFAR.

AB - Low frequency radio waves, while challenging to observe, are a rich source of information about pulsars. The LOw Frequency ARray (LOFAR) is a new radio interferometer operating in the lowest 4 octaves of the ionospheric "radio window": 10-240 MHz, that will greatly facilitate observing pulsars at low radio frequencies. Through the huge collecting area, long baselines, and flexible digital hardware, it is expected that LOFAR will revolutionize radio astronomy at the lowest frequencies visible from Earth. LOFAR is a next-generation radio telescope and a pathfinder to the Square Kilometre Array (SKA), in that it incorporates advanced multi-beaming techniques between thousands of individual elements. We discuss the motivation for low-frequency pulsar observations in general and the potential of LOFAR in addressing these science goals. We present LOFAR as it is designed to perform high-time-resolution observations of pulsars and other fast transients, and outline the various relevant observing modes and data reduction pipelines that are already or will soon be implemented to facilitate these observations. A number of results obtained from commissioning observations are presented to demonstrate the exciting potential of the telescope. This paper outlines the case for low frequency pulsar observations and is also intended to serve as a reference for upcoming pulsar/fast transient science papers with LOFAR.

KW - telescopes

KW - pulsars: general

KW - instrumentation: interferometers

KW - methods: observational

KW - stars: neutron

KW - ISM: general

KW - BINARY MILLISECOND PULSAR

KW - RADIO-CONTINUUM EMISSION

KW - DENSITY POWER SPECTRUM

KW - GAMMA-RAY PULSARS

KW - LOW-FREQUENCY

KW - INTERSTELLAR PLASMA

KW - FLUX DENSITIES

KW - NEUTRON-STARS

KW - DECAMETER WAVELENGTHS

KW - INTENSITY VARIATIONS

UR - http://adsabs.harvard.edu/abs/2011A%26A...530A..80S

U2 - 10.1051/0004-6361/201116681

DO - 10.1051/0004-6361/201116681

M3 - Article

SN - 0004-6361

VL - 530

JO - Astronomy & Astrophysics

JF - Astronomy & Astrophysics

M1 - A80

ER -

Observing pulsars and fast transients with LOFAR

Abstract

Keywords

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