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 by Staff Writers Amsterdam, Netherlands (SPX) Nov 16, 2017
An international team of astronomers led by the University of Amsterdam (The Netherlands) suspects that neutron stars with a strong magnetic field can still launch so-called jets. Since the 1980s, it was thought that strong magnetic fields inhibit the formation of these plasma streams. But observations with more advanced telescopes indicate jet-like radiation. The astronomers publish their findings in two articles in the Monthly Notices of the Royal Astronomical Society. Jets are energy rich plasma streams that are blown out of black holes or neutron stars at high speed. Jets have been known for decades, but so far no jets have been observed at neutron stars with a strong magnetic field. The prevailing assumption was that strong magnetic fields prevent the formation of jets. Since the eighties, astronomers hardly actively looked for jets at neutron stars with a strong magnetic field. In 2013, astronomer Nathalie Degenaar (University of Amsterdam, the Netherlands) decided that it was time to observe a few neutron stars with improved telescopes. She asked and got observing time with the Very Large Array (VLA), a radio telescope with 27 dishes in the state of New Mexico (USA). On June 6, 2013, and June 16, 2013, the VLA focused on the binary systems Her X-1 and GX 1+4 for a few dozens of minutes. Both systems consist of a neutron star with a very strong magnetic field and a normal star that orbits around it. Material flows from the normal star to the neutron star. The radio observations were intended to test whether these systems, with such a strong magnetic field, indeed do not launch a jet. The observational data was stocked for some time until the PhD student Jakob van den Eijnden (University of Amsterdam) started to crunch it in the summer of 2017. Van den Eijnden: "Analyzing this type of data from 27 telescopes together is complicated, so in June I went to Perth in Australia to learn from an expert how to do it." The analysis showed that both neutron stars emit radio radiation and that the intensity of that radiation is comparable to that of jets. The researchers do not claim that there are real jets, because for that claim additional measurements are needed. "However, we can now rule out a number of processes," says Van den Eijnden. "There is no so-called stellar wind. Her X-1 has no winds and the wind in GX 1+4 is not strong enough." It also seems, at least for Her X-1, that the radiation is not the result of shocks that emerge because gas of the donor star contacts the neutron star's magnetic field. And, again for Her X-1, there doesn't seem to be a so-called propeller. Van den Eijnden: "That's the case when the magnetic field is so strong that all the gas is blown away. You can compare it with a wet umbrella that rotates very fast so the drops fly away." The researchers have now applied for further observation time. They want to have a better look at Her X-1 and GX 1+4 to finally decide that they're launching jets. And they want to observe other similar neutron stars with strong magnetic fields to check if the observations are unique or just very common.
+ Discovery of Radio Emission from the Symbiotic X-ray Binary System GX 1+4, J. van den Eijnden, N. Degenaar, T. D. Russell, J. C. A. Miller-Jones, R. Wijnands, J. M. Miller, A. L. King, M. P. Rupen, 2017 accepted for publication in MRAS Letters
+ Radio Emission from the X-ray Pulsar Her X-1: A Jet Launched by a Strong Magnetic Field Neutron Star? J. van den Eijnden, N. Degenaar, T. D. Russell, J. C. A. Miller-Jones, R. Wijnands, J. M. Miller, A. L. King, M. P. Rupen, 2017, accepted for publication in MRAS Letters
Star kills its 'congenial' to form together a dwarf-binary systemSao Paulo, Brazil (SPX) Nov 10, 2017 A group of Brazilian astronomers observed a pair of celestial objects rarely seen in the Milky Way: a very low-mass white dwarf and a brown dwarf. What makes this binary system so unique is its origin: the white dwarf's existence was prematurely cut off by its companion, a brown dwarf, which caused its early death through "malnutrition" or loss of matter. A white dwarf is the endpoin ... read more Related Links Netherlands Research School For Astronomy Stellar Chemistry, The Universe And All Within It
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