茄子视频app官网

Menu

Wananga landing Wananga landing
News

Canterbury astronomers spot quadruple stars which may spark supernova explosions

13 May 2022

A quadruple star system discovered in 2017 and recently observed at the 茄子视频app官网 Mt John Observatory could represent a new channel by which thermonuclear supernova explosions can occur in the Universe, according to results published in Nature Astronomy today (13 May NZ time) by an international team of astronomers.

HOW TO APPLY

The rare double-binary star system HD74438 was discovered in the Vela constellation in 2017 using the Gaia-ESO Survey which characterised over 100,000 stars in our Milky Way Galaxy.

Follow-up observations of HD 74438 were obtained over several years to precisely track the orbits of the stars in the quadruple star system. Observations were taken with high-resolution spectrographs at the 茄子视频app官网 Mt John Observatory in New Zealand, and the Southern African Large Telescope in South Africa.

SDG 17 Sustainable Development Goal (SDG) 17 鈥 Partnership for the Goals

The astronomers were able to determine that this stellar quadruple is made up of four gravitationally bound stars: a short-period binary orbiting another short-period binary on a longer orbital period (2+2 configuration).

The quadruple system is a member of the young open star cluster IC 2391, making it the youngest (only 43-million years old) spectroscopic quadruple discovered in the Milky Way Galaxy to date, and among the quadruple systems with the shortest outer orbital period (six years).

In the听, the authors have shown that the gravitational effects of the outer binary system is changing the orbits of the inner binary, causing it to become more eccentric. State-of-the art simulations of this system鈥檚 future evolution show that such gravitational dynamics can lead to one or multiple collisions and merger events producing evolved dead stars (white dwarfs) with masses just below the Chandrasekhar limit. As a result of mass transfer or mergers, these white dwarf stars can produce a thermonuclear supernova explosion.

Astronomers involved in this study include the Director of the 茄子视频app官网 Mt John Observatory,听Associate Professor Karen Pollard听of the School of Physical and Chemical Sciences, 茄子视频app官网; UC alumni Dr C. Clare Worley and Professor Gerry Gilmore (), both of the Institute of Astronomy, Cambridge University, UK.

Associate Professor Pollard says high-precision and high-resolution spectroscopic observations were taken with the Hercules spectrograph on the 1.0m McLellan Telescope at the听茄子视频app官网 Mt John Observatory听in Tekapo.

鈥淎 star like our Sun will end its life as a small dense dead star known as a white dwarf, and the mass of white dwarfs cannot go above the so-called Chandrasekhar limit (about 1.4 times the mass of the Sun),鈥 she says. 鈥淚f it does, because of mass transfer or merger events, it can collapse and produce a thermonuclear supernova. Interestingly, 70% to 85% of all thermonuclear supernovae are now suspected to result from the explosion of white dwarfs with sub-Chandrasekhar masses. As a result of mass transfer or mergers, these white dwarf stars can explode as a thermonuclear supernova explosion.鈥

The evolution of stellar quadruples such as HD 74438 thus represents a new promising channel to form thermonuclear supernova explosions in the Universe, Associate Professor Pollard says.

Binary stars are now recognised to play a major role in a large range of astrophysical events, and mergers of binaries are the cause of the recent gravitational wave emission detection. Binary stars also allow us to derive fundamental stellar parameters like masses, radii and luminosities with a better accuracy compared to single stars. They represent the gems on which various astrophysics topics rely.

Stellar quadruples only represent a marginal fraction (a few percent) of all multiple systems. The complex evolution of such high-order multiples involves mass transfer and collisions, leading to mergers that are also possible progenitors of thermonuclear supernovae. These supernovae represent standard candles for fixing the Universe distance scale, even though the evolutionary channel(s) leading to the progenitors of such supernova explosions are still highly debated.

  • The paper, 鈥楢 spectroscopic quadruple as a possible progenitor of sub-Chandrasekhar type Ia supernovae鈥, has been published in听Nature Astronomy听on听12 May 2022 at 16:00 (London time),听12 May 2022 at 11:00 (US Eastern Time) 鈥 3am听today (13 May NZ time).听DOI: 10.1038/s41550-022-01664-5. Once published, it will be available at:听

More information
Visit our media enquiries page to contact UC Media.
What to read next
Privacy Preferences

By clicking "Accept All Cookies", you agree to the storing of cookies on your device to enhance site navigation, analyse site usage, and assist in our marketing efforts.