Stellar Shockwaves Shaped our Solar System
Stellar shockwaves shaped our solar system
Solar emissions rippling outward from our new-born Sun would have produced rings of material destined to form the planets. Credit: ESO/L. Calçada
The early years of our solar system were a turbulent time, and questions remain about its development. Dr. Tagir Abdylmyanov, Associate Professor from Kazan State Power Engineering University, has been researching shockwaves emitted from our very young sun, and has discovered that these would have caused the planets in our solar system to form at different times. Abdylmyanov will present his work at the European Planetary Science Congress in Madrid on Thursday 27th September.
Abdylmyanov has modeled the movements of particles in fluids and gases in the gas cloud from which our Sun accreted. His work suggests our new-born Sun emitted a series of shockwaves that rippled out into the remaining material. This created a series of debris rings around the Sun that accreted over millions of years into planets.
The research indicates that the first series of shockwaves during short but very rapid changes in solar activity would have created the proto-planetary rings for Uranus, Neptune, and dwarf planet Pluto. Jupiter, Saturn, and the asteroid belt would have come next during a series of less powerful shockwaves. Mercury, Venus, Earth, and Mars would have formed last, when the Sun was far calmer. This means that our own planet is one of the youngest in the solar system.
Solar shockwaves would have produced proto-planetary rings at different times, meaning the planets did not form simultaneously. Credit: ESO
“The planets formed in intervals — not altogether, as was previously thought,” Abdylmyanov explains. “It is difficult to say exactly how much time would have separated these groups, but the proto-planetary rings for Uranus, Neptune and Pluto would have likely formed very close to the Sun’s birth. 3 million years later and we would see the debris ring destined to form Saturn. Half a million years after this we would see something similar but for Jupiter. The asteroid belt would have begun to form about a million years after that, and another half a million years on we would see the very early stages of Mercury, Venus, Earth and Mars.”
Abdylmyanov hopes that this research will help us understand the development of planets around distant stars. “Studying the brightness of stars that are in the process of forming could give indications as to the intensity of stellar shockwaves. In this way we may be able to predict the location of planets around far-flung stars millions of years before they have formed.”