Why in news?
A recent study has provided new insights on the origins of the carbon in our galaxy.
Why study Carbon?
- Carbon is essential for life. It is the building block of all the complex organic molecules that our body need.
- It is known that all the carbon in the Milky Way came from dying stars that ejected the element into their surroundings.
How does carbon come from stars?
- Most stars except the most massive ones turn into white dwarfs.
- When the massive ones die, they go with a spectacular bang known as the supernova.
- Both low-mass and massive stars eject their ashes into the surroundings before they end their lives.
- And these ashes contain many different chemical elements, including carbon.
How is it synthesized?
- Both in low-mass stars and in massive stars carbon is synthesized in their deep and hot interiors through the triple-alpha reaction that is the fusion of three helium nuclei.
- In low-mass stars, the newly synthesized carbon is transported to the surface [from the interiors] via gigantic bubbles of gas and from there injected into the cosmos through stellar winds.
- Massive stars enrich the interstellar medium with carbon mostly before the supernova explosion, when they also experience powerful stellar winds.
Findings of the news research
- The new research suggests that white dwarfs may shed more light on carbon’s origin in the Milky Way.
- The researchers measured the masses of the white dwarfs, derived their masses at birth, and from there calculated the “initial-final mass relation”.
- The IFMR is a key astrophysical measure that integrates information of the entire life cycles of stars.
- They found that the relationship bucked a trend — that the more massive the star at birth, the more massive the white dwarf left at its death.
- So far, stars born roughly 1.5 billion years ago in our galaxy were thought to have produced white dwarfs about 60-65% the mass of our Sun.
What explains this?
- From an analysis of the initial-final mass relation around the little kink, the researchers drew their conclusions about the size range for the stars that contributed carbon to the Milky Way.
- Stars more massive than 2 solar masses, too, contributed to the galactic enrichment of carbon.
- Stars less massive than 1.65 solar masses did not. In other words 1.65-Msun [1.65 times the mass of the Sun] represents the minimum mass for a star to spread its carbon-rich ashes upon death.