Strong-field Gravity Tests with the Double Pulsar

M. Kramer (1; 2); I. H. Stairs (3); R. N. Manchester (4); N. Wex (1),; A. T. Deller (5,6); W. A. Coles (7); M. Ali (1; 8); M. Burgay (9); F. Camilo; (10); I. Cognard (11; 12); T. Damour (13); G. Desvignes (14; 1); R. D.; Ferdman (15); P. C. C. Freire (1); S. Grondin (3; 16); L. Guillemot; (11,; 12); G. B. Hobbs (4); G. Janssen (17; 18); R. Karuppusamy (1); D. R. Lorimer; (19); A. G. Lyne (2); J. W. McKee (1; 20); M. McLaughlin (19); L. E. Muench; (1); B. B. P. Perera (21); N. Pol (19; 22); A. Possenti (9; 23); J.; Sarkissian (4); B. W. Stappers (2); G. Theureau (11; 12; 24) ((1); Max-Planck-Institut fuer Radioastronomie; Bonn; Germany; (2) Jodrell Bank; Centre for Astrophysics; The University of Manchester; United Kingdom; (3); Department of Physics; Astronomy; University of British Columbia,; Vancouver; Canada; (4) Australia Telescope National Facility; CSIRO Space and; Astronomy; Australia; (5) Centre for Astrophysics; Supercomputing,; Swinburne University of Technology; Hawthorn; Australia; (6) ARC Centre of; Excellence for Gravitational Wave Discovery (OzGrav); Australia; (7); Electrical; Computer Engineering; University of California at San Diego,; USA; (8) Perimeter Institute for Theoretical Physics; Waterloo; Canada; (9); INAF - Osservatorio Astronomico di Cagliari; Italy; (10) South African Radio; Astronomy Observatory; South Africa; (11) Laboratoire de Physique et Chimie; de l'Environnement et de l'Espace LPC2E CNRS-Universite d'Orleans; France,; (12) Station de Radioastronomie de Nancay; Observatoire de Paris; CNRS/INSU,; France; (13) Institut des Hautes Etudes Scientifiques; Bures-sur-Yvette,; France; 14 LESIA; Observatoire de Paris; Universite PSL; CNRS; Universite de; Paris; France; (15) Faculty of Science; University of East Anglia; Norwich,; UK; (16) David A. Dunlap Department of Astronomy & Astrophysics; University; of Toronto; Canada; (17) ASTRON; Netherlands Institute for Radio Astronomy,; Dwingeloo; The Netherlands; (18) Department of Astrophysics/IMAPP; Radboud; University; Nijmegen; The Netherlands; (19) Department of Physics and; Astronomy; West Virginia University; Morgantown; USA; (20) Canadian Institute; for Theoretical Astrophysics; University of Toronto; Canada; (21) Arecibo; Observatory; University of Central Florida; Arecibo; USA; (22) Department of; Physics; Astronomy; Vanderbilt University; Nashville; USA; (23) Universita; di Cagliari; Dipartimento di Fisica; Italy; (24) Laboratoire Univers et; Theories LUTh; Observatoire de Paris; PSL Research University; CNRS/INSU,; Universite Paris Diderot; Meudon; France)

arXiv:2112.06795·astro-ph.HE·December 16, 2021

Strong-field Gravity Tests with the Double Pulsar

M. Kramer (1, 2), I. H. Stairs (3), R. N. Manchester (4), N. Wex (1),, A. T. Deller (5,6), W. A. Coles (7), M. Ali (1, 8), M. Burgay (9), F. Camilo, (10), I. Cognard (11, 12), T. Damour (13), G. Desvignes (14, 1), R. D., Ferdman (15), P. C. C. Freire (1), S. Grondin (3, 16)

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TL;DR

This paper reports on 16 years of observations of the Double Pulsar system, enabling unprecedented tests of strong-field gravity, detection of new relativistic effects, and validation of general relativity's predictions with high precision.

Contribution

The study provides the most comprehensive set of relativistic measurements in a binary pulsar, including the first observation of several predicted effects and high-precision tests of gravitational theories.

Findings

01

Detected seven post-Keplerian parameters, more than any other binary pulsar.

02

Validated general relativity's quadrupolar gravitational wave prediction at 0.013% level.

03

Observed new relativistic effects like light-bending and orbital deformation.

Abstract

Continued observations of the Double Pulsar, PSR J0737-3039A/B, consisting of two radio pulsars (A and B) that orbit each other with a period of 2.45hr in a mildly eccentric (e=0.088) binary system, have led to large improvements in the measurement of relativistic effects in this system. With a 16-yr data span, the results enable precision tests of theories of gravity for strongly self-gravitating bodies and also reveal new relativistic effects that have been expected but are now observed for the first time. These include effects of light propagation in strong gravitational fields which are currently not testable by any other method. We observe retardation and aberrational light-bending that allow determination of the pulsar's spin direction. In total, we have detected seven post-Keplerian (PK) parameters, more than for any other binary pulsar. For some of these effects, the measurement…

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