A Japanese space mission will deliver samples collected from asteroid Ryugu in a capsule to the outback desert of Woomera in South Australia this Sunday morning.
A leading expert from The Australian National University (ANU) who will analyze the samples says they could provide major insights into the origin of life on Earth.
The subsurface material collected from the asteroid will be dropped off by Hayabusa2. Testing will start almost immediately on the returned material.
The mission aims to shed light on the nature of asteroids and the origins of planets in our solar system, as well as the origin of Earth’s water, which is vital for all life.
ANU space rock expert Professor Trevor Ireland, who is on the Hayabusa2 science team, is in Woomera awaiting the arrival of the asteroid sample, which he will analyze in the lab.
“I anticipate that the Hayabusa2 samples of asteroid Ryugu will be very similar to the meteorite that fell in Australia near Murchison, Victoria, more than 50 years ago,” Professor Ireland, from the ANU Research School of Earth Sciences, said.
“The Murchison meteorite opened a window on the origin of organics on Earth because these rocks were found to contain simple
Amino acids are a set of organic compounds used to build proteins. There are about 500 naturally occurring known amino acids, though only 20 appear in the genetic code. Proteins consist of one or more chains of amino acids called polypeptides. The sequence of the amino acid chain causes the polypeptide to fold into a shape that is biologically active. The amino acid sequences of proteins are encoded in the genes. Nine proteinogenic amino acids are called “essential” for humans because they cannot be produced from other compounds by the human body and so must be taken in as food.
” class=”glossaryLink “>amino acids as well as abundant water.”
Professor Ireland said his work would help answer big questions about the diamond-shaped asteroid, which is about one kilometer in diameter and in an orbit that takes it between Earth and Mars.
“We will examine whether Ryugu is a potential source of organic matter and water on Earth when the solar system was forming and whether these still remain intact on the asteroid,” he said.
“This C-type asteroid, which is the most common kind, appears to be similar to the Murchison meteorites — rare carbonaceous chondrites packed with organic molecules and water.
“We might find that missing connection on Ryugu.
“We will also discover the history of this curious looking asteroid. The other rubble-pileasteroid Itokawa is quite young. Will Ryugu prove to be a lot older?”
ANU astronomer Dr. Brad Tucker said technology has enabled space missions to regularly land on objects in space and return back to Earth.
“With China’s Chang’e 5 mission landing on the Moon and returning in late December, Osiris-Rex and future missions planned, we’ll be able to get our hands dirty and learn a lot about the solar system and our own planet,” Dr. Tucker, from the ANU Research School of Astronomy and Astrophysics, said.
“Future space travel and exploration missions are going to be need to be able to extract resources in space. Missions like Hayabusa2 are laying the groundwork for this endeavor.”