The dwarf planet Ceres, which lies in the main asteroid belt between Mars and Jupiter, is not a barren space rock as earlier believed. New data from NASA's Dawn spacecraft have shown that it is a water-rich world.
After analysing data collected near the end of the mission, scientists determined that beneath the surface of Ceres, there could be a deep reservoir of brine, or salt-enriched water which is about 40 km deep and hundreds of miles wide.
"Dawn accomplished far more than we hoped when it embarked on its extraordinary extraterrestrial expedition," said Mission Director Marc Rayman of NASA's Jet Propulsion Laboratory in Southern California.
"These exciting new discoveries from the end of its long and productive mission are a wonderful tribute to this remarkable interplanetary explorer."
Ceres makes up almost a third of the asteroid belt's total mass, but it is still far smaller than Earth's Moon. The Dawn spacecraft arrived at Ceres in 2015.
Long before Dawn arrived at Ceres, scientists had noticed diffuse bright regions with telescopes, but their nature was unknown.
By the time the mission ended in October 2018, the orbiter had dipped to less than 35 km above the surface, revealing crisp details of the mysterious bright regions Ceres had become known for.
Scientists had figured out that the bright areas were deposits made mostly of sodium carbonate -- a compound of sodium, carbon, and oxygen.
They likely came from liquid that percolated up to the surface and evaporated, leaving behind a highly reflective salt crust.
But what they had not yet determined was where that liquid came from.
The new research revealed that the liquid came from sea water beneath its surface.
Ceres doesn't benefit from internal heating generated by gravitational interactions with a large planet, as is the case for some of the icy moons of the outer solar system.
But the new research, which focuses on Ceres' 92-kilometre-wide 'Occator' Crater -- home to the most extensive bright areas -- confirms that Ceres is a water-rich world like these other icy bodies.
The research not only confirmed that the bright regions are young -- some less than two million years old -- it also found that the geologic activity driving these deposits could be ongoing.
The findings appeared in a special collection of papers published by Nature Astronomy, Nature Geoscience, and Nature Communications on Monday.
(Only the headline and picture of this report may have been reworked by the Business Standard staff; the rest of the content is auto-generated from a syndicated feed.)
Business Standard has always strived hard to provide up-to-date information and commentary on developments that are of interest to you and have wider political and economic implications for the country and the world. Your encouragement and constant feedback on how to improve our offering have only made our resolve and commitment to these ideals stronger. Even during these difficult times arising out of Covid-19, we continue to remain committed to keeping you informed and updated with credible news, authoritative views and incisive commentary on topical issues of relevance.
We, however, have a request.
As we battle the economic impact of the pandemic, we need your support even more, so that we can continue to offer you more quality content. Our subscription model has seen an encouraging response from many of you, who have subscribed to our online content. More subscription to our online content can only help us achieve the goals of offering you even better and more relevant content. We believe in free, fair and credible journalism. Your support through more subscriptions can help us practise the journalism to which we are committed.
Support quality journalism and subscribe to Business Standard.