Supernova SN 1006, The Brightest Stellar Event In Recorded History Explained

Published on September 27th, 2012 | by

September 27th, 2012 by

The brightest stellar event in recorded history occurred in 1006, between April 30th and May 1st. It was a supernova that was so bright and large that it was observed by a variety of different civilizations throughout the world at the time. And now, after more than a thousand years, researchers think that they have determined that the super bright supernova was caused by the merger of two white dwarfs.


Among those civilizations that observed the supernova, Chinese astronomers noted that the stellar event remained visible for three years. But the most specific account was taken by the Egyptian astronomer and doctor Ali ibn Ridwan (988-1061). He noted that, in the Egyptian skies, the stellar event was around three times brighter than the planet Venus, and that, amazingly, it created nearly a fourth of the light that the full Moon did.

The co-director of the research, Pilar Ruiz-Lapuente, from the Institute of Cosmos Sciences (ICCUB) and the Instituto of Fundamental Physics (IFF-CSIC), says: “In this work the existing stars in the area have been studied, regarding distance and possible contamination by elements of the supernova, and the results show that there is no star that could be considered the progenitor of this explosion.”

The lead IAC researcher and the lead author of the study, Jonay González Hernández, says: “We have conducted an exhaustive exploration of the area around where the explosion of the supernova of 1006 occurred and have found nothing, which invites us to think that this event was probably the result of a collision and merger of two white dwarf stars of similar mass.”

A Universitat de Barcelona news release on the research notes:

“The supernova SN 1006 is of the type that occurs in binary systems, those consisting of two astronomical objects bound together by their gravitational pull. These systems can be formed by a white dwarf and a normal stellar companion that contributes the matter necessary for it to reach a critical mass of 1.4 times the mass of the Sun, the so-called Chandrasekhar limit. Once this mass is reached, the stars explode in a supernova. Another possibility is that the system comprises two white dwarfs that eventually merge to create a supernova.”

Ruiz-Lapuente continues: “This new result, together with others previous, suggests that the merger of white dwarfs could be a common pathway that leads to these violent thermonuclear explosions.”

And here’s more from the Universitat de Barcelona news release:

“Supernovae are explosions that occur between stars in the last stage of their lives. They produce a large release of energy and expel huge amounts of matter at high velocity into the interstellar medium. Specifically, a supernova of the type of that occurred in 1006 is caused by a thermonuclear explosion when a white dwarf’s mass reaches the Chandrasekhar limit, most likely expelling all its matter and leaving no stellar remnant of the explosion.

“The final clue that led the researchers to conclude that in this case there had been a merger of two white dwarfs was that this supernova, about 7,000 light years from Earth, has no stellar companion to the white dwarf progenitor. However, an explosion produced by the merger of two white dwarfs leaves no trace, except for the supernova remnant that can be studied until centuries later, as in the case of SN 1006, one of only four historical supernovae of this type that have occurred in the Milky Way.

“The study utilized an UVES high-resolution spectrograph installed in one of four European VLT telescopes, of 8 metres in diameter, belonging to the European Southern Observatory (ESO, Chile), with which the stars around the site of the explosion were observed.”

González Hernández analyzed in great detail the spectroscopic and photometric data obtained: “Analysis of the stars in the area of the explosion discarded them as possible companions of the progenitor star of the supernova of 1006,” he said.

“The astrophysicists analyzed different types of stars in the area: giants, subgiants and dwarfs,” Universitat de Barcelona adds.

According to Gonzalez: “Only four giant stars are found at the same distance as the remnant of the supernova of 1006, some 7,000 light years from Earth, but the numerical simulations do not predict a companion of these characteristics. The appearance of a possible stellar companion, even a thousand years after the violent impact of an explosion of this type, would not be that of a normal giant star.”

And here’s more from the news release again:

“White dwarfs are stars in the last stage of their lives of a mass less than 1.4 times that of the Sun. These stars, or stellar remnants, have exhausted their energy sources and are in a process of very gradual cooling. Stars of less than 8-10 solar masses, that is, the vast majority of stars in the Milky Way, as well as the Sun, end their life cycles as white dwarfs.

“From the theoretical point of view the study, which also involved the UB researchers Ramon Canal and Javier Mendez, also shows that the merger of stars of this type is consistent with existing stellar event.

“Already in 2004 this research group had identified another star as the stellar companion of the supernova of 1572.”

“Then, we explored another region near the centre of the remnant of Tycho’s supernova and found a subgiant star of similar temperature to the Sun, which could be the companion to the progenitor star of the supernova of 1572,” Pilar Ruiz-Lapuente comments. “In this new study, our intention was to look for the companion of the supernova of 1006, but, to our surprise, we did not find one.”

“In 1997 Ruiz-Lapuente began study of the remnants of Type Ia supernovae with this method of searching for progenitor stars. To date, five supernovae have been studied, of which a companion has only been found in the case of Tycho Brahe’s 1572 supernova, SN 1572.”

He explains: “We intend to continue studying supernovae remnants to determine the frequency of the merger of white dwarfs as a pathway. The next will be Kepler’s supernova of 1604.”

The research was just published in the journal Nature.

Source: Universitat de Barcelona
Image Credits: NASA, ESA, Zolt Levay (STScI); Pete Challis (CfA)

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