Curtin University: Curtin researchers locate largest known fresh meteorite strikes on Mars
The only Australian representatives on a NASA-led international research team, the two Curtin scientists helped make the rare discovery of two impact craters larger than 130 meters in diameter each, which were formed on Mars in the second half of 2021.
Research co-author Associate Professor Katarina Miljkovic, from Curtin’s Space Science and Technology Centre and the School of Earth and Planetary Sciences, said the discovery of the craters was made through the use of both NASA’s imaging technology and seismometers.
“As well as NASA’s Mars Reconnaissance Orbiter imager, the NASA InSight seismometers were operating in the second half of 2021, which is when these impacts were recorded as having occurred,” Associate Professor Miljkovic said.
“They have detected these impact events in the form of large seismic activity or a ‘bang’, firstly as the meteorite passed through the atmosphere and then again as it hit the ground.
“Impact events happen all the time on both Earth and Mars, but generally involve small rocks from space that only graze the atmosphere. On occasion, we get impacts that can penetrate deeper into the atmosphere to form a noticeable bang in the atmosphere or on the ground, which was the case here.”
Co-author PhD student Andrea Rajšić, who completed the research while at Curtin’s Space Science and Technology Centre, said because the meteorite impacts were large, they penetrated deeper into the planet and had generated the only two quakes known to have been caused by meteorite impacts on Mars.
“There are not that many large quakes detected on Mars, whether they be driven by interior geological forces or in this case external impacts, but when they do occur, they help with deep-interior mapping of Mars,” Ms Rajšić said.
“Impact events are extremely helpful in seismology because they can be considered as a constrained seismic source with a known location. This is a fantastic way to peek into the interior structure of the Red Planet.”
Associate Professor Miljkovic said one of the impacts had excavated ice at the lowest altitude ever observed on Mars, which would help contribute to our subsurface understanding of the Mars water ice reservoir.
“This knowledge is useful for many reasons, from the potential future habitation of Mars by humans and their ability to locate water as a resource to the fundamental understanding of the structure of Mars as a planet. If we are to understand the formation and evolution of our own planet, we ought to understand other terrestrial planets too,” Associate Professor Miljkovic said.
Dr Rajšić completed her PhD studies contributing to this work at the Space Science and Technology Centre at Curtin. Curtin’s contribution to this research was funded by the Australian Research Council.