An international team of astronomers has used the NASA/ESA Hubble Space Telescope to observe N103B, a supernova remnant in our neighboring galaxy the Large Magellanic Cloud.
This Hubble image shows the supernova remnant N103B (top of the image). N103B was a Type Ia supernova, located in the Large Magellanic Cloud. Owing to its relative proximity to Earth, astronomers observe the remnant to search for a potential stellar survivor of the explosion. The orange-red filaments visible in the image show the shock fronts of the supernova explosion. These filaments allow astronomers to calculate the original centre of the explosion. The filaments also show that the explosion is no longer expanding as a sphere, but is elliptical in shape. Astronomers assume that part of material ejected by the explosion hit a denser cloud of interstellar material, which slowed its speed. The shell of expanding material being open to one side supports this idea. The gas in the lower half of the image and the dense concentration of stars in the lower left are the outskirts of the rich star cluster NGC 1850. Image credit: NASA / ESA / Hubble.
Also known as SNR 0509-68.7 and SNR J050854-684447, N103B is a remnant of a Type Ia supernova.
This object lies in the outskirts of the ‘cosmic superbubble’ around the rich star cluster known as NGC 1850, which is located in the Large Magellanic Cloud, just over 160,000 light-years from Earth.
In contrast to many other supernova remnants N103B does not appear to have a spherical shape but is strongly elliptical.
Astronomers assume that part of material ejected by the explosion hit a denser cloud of interstellar material, which slowed its speed. The shell of expanding material being open to one side supports this idea.
The predictable luminosity of Type Ia supernovae means that astronomers can use them as cosmic standard candles to measure their distances, making them useful tools in studying the cosmos. Their exact nature, however, is still a matter of debate.
Scientists suspect that Type Ia supernovae occur in binary systems in which at least one of the stars in the pair is a white dwarf.
There are currently two main theories describing how these binary systems become supernovae:
(i) one theory assumes that both stars in the binary are white dwarfs; if the stars merge with one another it would ultimately lead to a supernova explosion of Type Ia;
(ii) the second theory proposes that only one star in the system is a white dwarf, while its companion is a normal star; in this theory material from the companion star is accreted onto the white dwarf until its mass reaches a limit, leading to a dramatic explosion; in that scenario, the theory indicates that the normal star should survive the blast in at least some form; however, to date no residual companion around any Type Ia supernova has been found.
Dr. Chuan-Jui Li, an astronomer at the Academia Sinica Institute of Astronomy and Astrophysics and the National Taiwan University, and his colleagues from Taiwan, the United States, Switzerland, and Chile observed the supernova remnant N103B in a search for such a companion.
The team looked at the region in H-alpha — which highlights regions of gas ionized by the radiation from nearby stars — to locate supernova shock fronts.
The researchers hoped to find a star near the centre of the explosion which is indicated by the curved shock fronts.
The discovery of a surviving companion would put an end to the ongoing discussion about the origin of Type Ia supernova.
And indeed they found one candidate star that meets the criteria — for star type, temperature, luminosity and distance from the centre of the original supernova explosion.
This star has approximately the same mass as the Sun, but it is surrounded by an envelope of hot material that was likely ejected from the pre-supernova system.
Although this star is a reasonable contender for N103B’s surviving companion, its status cannot be confirmed yet without further investigation and a spectroscopic confirmation. The search is still ongoing.
This research was presented in a paper published in the Astrophysical Journal on February 10, 2017. The article is also publicly available at arXiv.org.
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Chuan-Jui Li et al. 2017. Physical Structures of the Type Ia Supernova Remnant N103B. ApJ 836, 85; doi: 10.3847/1538-4357/836/1/85
