National Aeronautics and Space Administration Logo
Follow this link to skip to the main content NASA Banner
Solar System Exploration
News & Events
Swept Away: Study Suggests Massive Water Erosion of Mars' Highlands
Swept Away: Study Suggests Massive Water Erosion of Mars' Highlands
16 May 2001
(Source: Washington University in St. Louis)

http://news-info.wustl.edu/News/nrindex00/mars2.html

News Release
Washington University in St. Louis

Contact:
Tony Fitzpatrick or
Trent Stockton
(314) 935-5257

St. Louis, Mo., May 16, 2001 - Massive erosion shaped the surface of Mars, according to planetary scientists at Washington University in St. Louis.

Brian M. Hynek, doctoral candidate in Earth and Planetary Sciences, and Roger J. Phillips, Ph.D., professor of earth and planetary sciences and director of Washington University's McDonnell Center for the Space Sciences, suggest that western Arabia Terra, an area the size of the European continent, experienced an extensive erosion event caused by flowing water.

"We argue that this entire region has been massively eroded," said Hynek. "The region used to look like the rest of the highlands, but a vertical kilometer of material - enough to fill the Gulf of Mexico - has been relocated downslope and spread out into the northern plains."

The researchers used high-resolution topographic data from the Mars Orbiter Laser Altimeter (MOLA) instrument on the Mars Global Surveyor mission to construct detailed maps of the planet's surface. "Before this mission, topography was known only within a kilometer at best; now we are accurate to within half a meter at any given point on the surface of Mars," said Hynek.

MOLA's accuracy, and the more than half a billion data points it has collected, reveals many previously unknown features of Mars' surface. The research was published in the May issue of the journal Geology.

Mars is divided into two main areas: the older Southern Highlands with lots of craters and valley networks, and the younger Northern Lowlands with few craters and no valley networks.

When the researchers began studying maps from the new data, they noticed that one region, western Arabia Terra, is a kilometer lower than the rest of the highlands and borders the lowlands to the north. Before the Mars Global Surveyor mission, this region was lumped in with the rest of the highlands. But the new topography reveals that there is much more going on here than previously thought. Looking carefully at western Arabia, they noticed that it differs from the rest of the highlands in having very few large craters, and only a few traces of valley networks, and numerous erosional remnants.

"This combination makes it very likely that the entire region was swept away," said Hynek.

But how can you remove all this material and carry it away?

"Lots of things can erode planets. Wind is very effective on long timescales; volcanoes, ice and glaciers can all erode features, but on this large of a scale these are unlikely explanations," said Hynek. He said that the massive size of the eroded area and the remnants of valley networks suggest running water was responsible.

The researchers believe the erosion event took place very early in Mars' history, during the Late Noachian, and ended by around 3.8 to 3.5 million years ago. The timing coincides with other water features found on the planet and heavy outflow of lava from volcanoes early in Mars' history, as the researchers noted in the journal Science earlier this year. Volcanic eruptions emit great amounts of water, carbon dioxide, sulfur and other greenhouse gases as well as lava and ash. This could have led to the development of an atmosphere on Mars that persisted for a few hundred million years - long enough to raise surface temperature above freezing and maintain liquid water on the planet's surface.

"Mars has not always been cold and dry with little happening on the surface. At one time it had a heyday," said Hynek.

The researchers are now focusing attention on a large outcrop of hematite occurring within western Arabia Terra, the Terra Meridiani region. Hematite, an iron oxide, forms in the presence of water on Earth.

"This is very likely to be one of two Mars Rover landing sites in 2004," said Hynek. "We want to go where the water was."

News Archive Search  Go!
Show  results per page
 
 
Awards and Recognition   Solar System Exploration Roadmap   Contact Us   Site Map   Print This Page
NASA Official: Kristen Erickson
Advisory: Dr. James Green, Director of Planetary Science
Outreach Manager: Alice Wessen
Curator/Editor: Phil Davis
Science Writer: Autumn Burdick
Producer: Greg Baerg
Webmaster: David Martin
> NASA Science Mission Directorate
> Budgets, Strategic Plans and Accountability Reports
> Equal Employment Opportunity Data
   Posted Pursuant to the No Fear Act
> Information-Dissemination Policies and Inventories
> Freedom of Information Act
> Privacy Policy & Important Notices
> Inspector General Hotline
> Office of the Inspector General
> NASA Communications Policy
> USA.gov
> ExpectMore.gov
> NASA Advisory Council
> Open Government at NASA
Last Updated: 5 Jun 2001