The first six months of the Advanced LIGO’s and Advanced Virgo’s third observing run with GRANDMA

We present the Global Rapid Advanced Network Devoted to the Multi-messenger Addicts (GRANDMA). The network consists of 21 telescopes with both photometric and spectroscopic facilities. They are connected together thanks to a dedicated infrastructure. The network aims at coordinating the observations of large sky position estimates of transient events to enhance their follow-up and reduce the delay between the initial detection and optical confirmation. The GRANDMA programme mainly focuses on follow-up of gravitational-wave alerts to find and characterize the electromagnetic counterpart during the third observational campaign of the Advanced LIGO and Advanced Virgo detectors. But it allows for follow-up of any transient alerts involving neutrinos or gamma-ray bursts, even those with poor spatial localization. We present the different facilities, tools, and methods we developed for this network and show its efficiency using observations of LIGO/Virgo S190425z, a binary neutron star merger candidate. We furthermore report on all GRANDMA follow-up observations performed during the first six months of the LIGO–Virgo observational campaign, and we derive constraints on the kilonova properties assuming that the events’ locations were imaged by our telescopes.

[1]  Y. N. Liu,et al.  Multi-messenger Observations of a Binary Neutron Star Merger , 2019, Proceedings of Multifrequency Behaviour of High Energy Cosmic Sources - XIII — PoS(MULTIF2019).

[2]  P. Fryzlewicz,et al.  Detection of gamma-ray transients with wild binary segmentation , 2019, Monthly Notices of the Royal Astronomical Society.

[3]  Y. G. Yang,et al.  The mini-GWAC optical follow-up of gravitational wave alerts – results from the O2 campaign and prospects for the upcoming O3 run , 2019, Research in Astronomy and Astrophysics.

[4]  B. Metzger Lessons from the light of a neutron star merger , 2019, Annals of Physics.

[5]  A. Klotz,et al.  Limits on the Electromagnetic Counterpart of Binary Black Hole Coalescence at Visible Wavelengths , 2019, The Astrophysical Journal.

[6]  N. Christensen,et al.  Optimizing multitelescope observations of gravitational-wave counterparts , 2019, Monthly Notices of the Royal Astronomical Society.

[7]  P. Cowperthwaite,et al.  The Optical Afterglow of GW170817: An Off-axis Structured Jet and Deep Constraints on a Globular Cluster Origin , 2019, The Astrophysical Journal.

[8]  Eugene Serabyn,et al.  GROWTH on S190425z: Searching Thousands of Square Degrees to Identify an Optical or Infrared Counterpart to a Binary Neutron Star Merger with the Zwicky Transient Facility and Palomar Gattini-IR , 2019, The Astrophysical Journal.

[9]  M. S. Shahriar,et al.  Low-latency Gravitational-wave Alerts for Multimessenger Astronomy during the Second Advanced LIGO and Virgo Observing Run , 2019 .

[10]  B. Metzger,et al.  Multimessenger Bayesian parameter inference of a binary neutron star merger , 2018, Monthly Notices of the Royal Astronomical Society: Letters.

[11]  K. Ackley,et al.  Joint gravitational wave - gamma-ray burst detection rates in the aftermath of GW170817 , 2018, Proceedings of The New Era of Multi-Messenger Astrophysics — PoS(Asterics2019).

[12]  D. Radice,et al.  Multimessenger parameter estimation of GW170817 , 2018, The European Physical Journal A.

[13]  B. A. Boom,et al.  A Fermi Gamma-Ray Burst Monitor Search for Electromagnetic Signals Coincident with Gravitational-wave Candidates in Advanced LIGO ʼ s First Observing Run , 2022 .

[14]  G. Smoot,et al.  Mergers of black hole–neutron star binaries and rates of associated electromagnetic counterparts , 2018, Monthly Notices of the Royal Astronomical Society.

[15]  T Sakamoto,et al.  A year in the life of GW170817: the rise and fall of a structured jet from a binary neutron star merger , 2018, Monthly Notices of the Royal Astronomical Society.

[16]  A. Melandri,et al.  Compact radio emission indicates a structured jet was produced by a binary neutron star merger , 2018, Science.

[17]  Kento Masuda,et al.  A Hubble constant measurement from superluminal motion of the jet in GW170817 , 2018, Nature Astronomy.

[18]  S. Smartt,et al.  LIGO/Virgo S190425z - ePESSTO+ spectrum of PS19qp shows red featureless source at z=0.037. , 2019 .

[19]  G. Greco,et al.  LIGO/Virgo S190425z: GRAWITA TNG observations of ZTF19aarzaod. , 2019 .

[20]  C. Casentini,et al.  LIGO-Virgo S190425z: AGILE MCAL observation. , 2019 .

[21]  P. Raffai,et al.  LIGO/Virgo S190426c: Potential host galaxies from the GLADE catalog. , 2019 .

[22]  A. Coleiro,et al.  LIGO/Virgo S190503bf: INTEGRAL prompt observation. , 2019 .

[23]  Martina Cardillo,et al.  LIGO/Virgo S190503bf: AGILE-GRID Observations. , 2019 .

[24]  A. T. Deller,et al.  Superluminal motion of a relativistic jet in the neutron-star merger GW170817 , 2018, Nature.

[25]  S. Smartt,et al.  Constraints on the neutron star equation of state from AT2017gfo using radiative transfer simulations , 2018, Monthly Notices of the Royal Astronomical Society.

[26]  Rafael S. de Souza,et al.  GLADE: A galaxy catalogue for multimessenger searches in the advanced gravitational-wave detector era , 2018, Monthly Notices of the Royal Astronomical Society.

[27]  N. Tanvir,et al.  Low-frequency View of GW170817/GRB 170817A with the Giant Metrewave Radio Telescope , 2018, The Astrophysical Journal.

[28]  M. Chan,et al.  Optimizing searches for electromagnetic counterparts of gravitational wave triggers , 2018, 1803.02255.

[29]  Iair Arcavi,et al.  The First Hours of the GW170817 Kilonova and the Importance of Early Optical and Ultraviolet Observations for Constraining Emission Models , 2018, 1802.02164.

[30]  T. Sakamoto,et al.  The outflow structure of GW170817 from late-time broad-band observations , 2018, 1801.06516.

[31]  C. Guidorzi,et al.  The Binary Neutron Star Event LIGO/Virgo GW170817 160 Days after Merger: Synchrotron Emission across the Electromagnetic Spectrum , 2018, 1801.03531.

[32]  J. P. Osborne,et al.  The optical afterglow of the short gamma-ray burst associated with GW170817 , 2018, Nature Astronomy.

[33]  J. Ruan,et al.  Brightening X-Ray Emission from GW170817/GRB 170817A: Further Evidence for an Outflow , 2017, 1712.02809.

[34]  Sebastiano Bernuzzi,et al.  GW170817: Joint Constraint on the Neutron Star Equation of State from Multimessenger Observations , 2017, 1711.03647.

[35]  P. Ferreira,et al.  Strong Constraints on Cosmological Gravity from GW170817 and GRB 170817A. , 2017, Physical review letters.

[36]  David Blair,et al.  Gravitational Waves and Gamma-rays from a Binary Neutron Star Merger: GW170817 and GRB 170817A , 2017, 1710.05834.

[37]  L. S. Collaboration,et al.  Gravitational Waves and Gamma-rays from a Binary Neutron Star Merger: GW170817 and GRB 170817A , 2017 .

[38]  B. A. Boom,et al.  GW170817: Observation of Gravitational Waves from a Binary Neutron Star Inspiral. , 2017, Physical review letters.

[39]  B. Metzger,et al.  Origin of the heavy elements in binary neutron-star mergers from a gravitational-wave event , 2017, Nature.

[40]  T. Sakamoto,et al.  The X-ray counterpart to the gravitational-wave event GW170817 , 2017, Nature.

[41]  F. Vernizzi,et al.  Dark Energy after GW170817 and GRB170817A. , 2017, Physical review letters.

[42]  J. Ezquiaga,et al.  Dark Energy After GW170817: Dead Ends and the Road Ahead. , 2017, Physical review letters.

[43]  Texas Tech University,et al.  Multi-messenger observations of a binary neutron star merger , 2017, 1710.05833.

[44]  M. M. Kasliwal,et al.  A radio counterpart to a neutron star merger , 2017, Science.

[45]  E. Bozzo,et al.  INTEGRAL Detection of the First Prompt Gamma-Ray Signal Coincident with the Gravitational-wave Event GW170817 , 2017, 1710.05449.

[46]  C. Tao,et al.  Follow Up of GW170817 and Its Electromagnetic Counterpart by Australian-Led Observing Programmes , 2017, Publications of the Astronomical Society of Australia.

[47]  Chris L. Fryer,et al.  Swift and NuSTAR observations of GW170817: Detection of a blue kilonova , 2017, Science.

[48]  D. Frail,et al.  Illuminating gravitational waves: A concordant picture of photons from a neutron star merger , 2017, Science.

[49]  C. A. Wilson-Hodge,et al.  An Ordinary Short Gamma-Ray Burst with Extraordinary Implications: Fermi-GBM Detection of GRB 170817A , 2017, 1710.05446.

[50]  J. K. Blackburn,et al.  A gravitational-wave standard siren measurement of the Hubble constant , 2017, Nature.

[51]  Michael Purrer,et al.  Statistical Gravitational Waveform Models: What to Simulate Next? , 2017, 1706.05408.

[52]  B. Metzger,et al.  Kilonovae , 2016, Living Reviews in Relativity.

[53]  D. Coward,et al.  The Zadko Telescope: Exploring the Transient Universe , 2016, Publications of the Astronomical Society of Australia.

[54]  William H. Lee,et al.  The Deep and Transient Universe in the SVOM Era: New Challenges and Opportunities - Scientific prospects of the SVOM mission , 2016, 1610.06892.

[55]  P. Graff,et al.  GOING THE DISTANCE: MAPPING HOST GALAXIES OF LIGO AND VIRGO SOURCES IN THREE DIMENSIONS USING LOCAL COSMOGRAPHY AND TARGETED FOLLOW-UP , 2016, 1603.07333.

[56]  S. Bose,et al.  An Enhanced Method for Scheduling Observations of Large Sky Error Regions for Finding Optical Counterparts to Transients , 2016, 1603.01689.

[57]  Steven Bloemen,et al.  Tiling strategies for optical follow-up of gravitational wave triggers by wide field of view telescopes , 2015, 1511.02673.

[58]  Mansi M. Kasliwal,et al.  GALAXY STRATEGY FOR LIGO-VIRGO GRAVITATIONAL WAVE COUNTERPART SEARCHES , 2015, 1508.03608.

[59]  B. Metzger,et al.  Neutron-powered precursors of kilonovae , 2014, 1409.0544.

[60]  The Ligo Scientific Collaboration Advanced LIGO , 2014, 1411.4547.

[61]  Piotr Fryzlewicz,et al.  Wild binary segmentation for multiple change-point detection , 2014, 1411.0858.

[62]  J. Camp,et al.  HIGH-ENERGY ELECTROMAGNETIC OFFLINE FOLLOW-UP OF LIGO-VIRGO GRAVITATIONAL-WAVE BINARY COALESCENCE CANDIDATE EVENTS , 2014, 1410.0929.

[63]  C. Broeck,et al.  Advanced Virgo: a second-generation interferometric gravitational wave detector , 2014, 1408.3978.

[64]  F. Ohme,et al.  PROSPECTS FOR JOINT GRAVITATIONAL-WAVE AND ELECTROMAGNETIC OBSERVATIONS OF NEUTRON-STAR–BLACK-HOLE COALESCING BINARIES , 2014, 1406.6057.

[65]  Tum,et al.  Comprehensive nucleosynthesis analysis for ejecta of compact binary mergers , 2014, 1406.2687.

[66]  F. Barone,et al.  Advanced Virgo: a 2nd generation interferometric gravitational wave detector , 2014 .

[67]  H. Janka,et al.  Prompt merger collapse and the maximum mass of neutron stars. , 2013, Physical review letters.

[68]  Mansi Kasliwal,et al.  IDENTIFYING ELUSIVE ELECTROMAGNETIC COUNTERPARTS TO GRAVITATIONAL WAVE MERGERS: AN END-TO-END SIMULATION , 2012, 1210.6362.

[69]  Xiaofeng Wang,et al.  The photometric system of the Tsinghua-NAOC 80-cm telescope at NAOC Xinglong Observatory , 2012, 1205.6529.

[70]  A. Klotz,et al.  The Zadko Telescope: A Southern Hemisphere Telescope for Optical Transient Searches, Multi-Messenger Astronomy and Education , 2010, Publications of the Astronomical Society of Australia.

[71]  S. Roweis,et al.  ASTROMETRY.NET: BLIND ASTROMETRIC CALIBRATION OF ARBITRARY ASTRONOMICAL IMAGES , 2009, 0910.2233.

[72]  M. Boër,et al.  Robotic Observations of the Sky with TAROT: 2004–2007 , 2008 .

[73]  Aziz Ziad,et al.  The astroclimate of Maidanak Observatory in Uzbekistan , 2000 .

[74]  E. Bertin,et al.  SExtractor: Software for source extraction , 1996 .

[75]  M. Bessell,et al.  UBVRI PASSBANDS. , 1990 .

[76]  M. Livio,et al.  Nucleosynthesis, neutrino bursts and γ-rays from coalescing neutron stars , 1989, Nature.