Researchers from the UPC and the IAC discover one of the most massive neutron stars

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The massive pulsar in the binary system PSR J2215+5135, illustrated in the figure, heats up the inner face of its companion star. Credit: G. Pérez-Díaz/IAC.

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Using a pioneering method, the team has measured the velocity of both sides of the companion. Credit: G. Pérez-Díaz/IAC, R. Hynes.

Using a pioneering method, researchers from the Astronomy and Astrophysics Group of the UPC and the Canary Islands Institute of Astrophysics (IAC) have found a neutron star of about 2.3 Solar masses—one of the most massive ever detected. The study was published on the 23rd of May in The Astrophysical Journal and opens a new path of knowledge in many fields of astrophysics and nuclear physics.

May 24, 2018

Neutron stars (often called pulsars) are stellar remnants that have reached the end of their evolutionary life: they result from the death of a star of between 10 and 30 Solar masses. Despite their small size (about 20 kilometres in diameter), neutron stars have more mass than the Sun, so they are extremely dense.

Researchers from the Universitat Politècnica de Catalunya (UPC) and the Canary Islands Institute of Astrophysics (IAC) used an innovative method to measure the mass of one of the heaviest neutron stars known to date. Discovered in 2011 and called PSR J2215+5135, with about 2.3 Solar masses it is one of the most massive of the more than 2,000 neutron stars known to date. Although a study published in 2011 reported evidence of a neutron star with 2.4 Solar masses, the most massive neutron stars that had previously achieved a consensus among scientists, reported in 2010 and 2013, have 2 Solar masses.

The study was led by Manuel Linares, Marie-Curie researcher of the Astronomy and Astrophysics Group (GAA), linked to the UPC's Department of Physics, in collaboration with the astronomers Tariq Shahbaz and Jorge Casares of the IAC. The researchers used data obtained from the Gran Telescopio Canarias (GTC), the largest optical and infrared telescope in the world, the William Herschel Telescope (WHT), the Isaac Newton Telescope Group (ING) and the IAC-80 telescope, in combination with dynamical models of binary stars with irradiation. An article reporting on the results of the study, entitled “Peering into the dark side: magnesium lines establish a massive neutron star in PSR J2215+5135”, was published in The Astrophysical Journal.

A pioneering measurement method
The team developed a more accurate method than those used to date to measure the mass of neutron stars in compact binaries. PSR J2215+5135 is part of a binary system, in which two stars orbit around a common centre of mass: a “normal” star (like the Sun) “accompanies” the neutron star. The secondary or companion star is strongly irradiated by the neutron star.

The more massive the neutron star is, the faster the companion star moves in its orbit. The novel method uses spectral lines of hydrogen and magnesium to measure the speed at which the companion star moves. This allowed the team led by Manuel Linares to measure for the first time the speed of both sides of the companion star (the irradiated side and the shaded side), and to show that a neutron star can have more than twice the Sun’s mass.

This new method can also be applied to the rest of this growing population of neutron stars: over the last 10 years, the Fermi-LAT NASA gamma ray telescope has revealed dozens of pulsars similar to PSR J2215+5135. In principle, the method can also be used to measure the mass of black holes and white dwarfs (remnants of stars that die with more than 30 or fewer than 10 Solar masses, respectively) when they are found in similar binary systems in which irradiation is important.

Denser than an atomic nucleus
Being able to determine the maximum mass of a neutron star has very important consequences for many fields of astrophysics, as well as for nuclear physics. The interactions between nucleons (the neutrons and protons that make up the nucleus of an atom) at high densities are one of the great mysteries of physics today. Neutron stars are a natural laboratory for studying the densest and most exotic states of matter that can be imagined.

The results of the project also suggest that in order to support the weight of 2.3 Solar masses, the repulsion between particles in the nucleus of the neutron star must be sufficiently strong. This would indicate that we are unlikely to find free quarks or other exotic forms of matter in the centre of the neutron star.


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