April 21, 2008
The Johns Hopkins University Applied Physics Laboratory
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New Online Map Reveals Evidence of the Forces that Once Shaped Mars
A new online map lets visitors explore Mars' past through a collection of high-resolution observations from one of the most powerful spectrometers ever sent to the Red Planet. Evidence of ancient bodies of water, flowing rivers and groundwater peeks out from beneath layers of hardened magma and dust—testaments to Mars' progression through wet, volcanic and dry eras.
The data come from the Compact Reconnaissance Imaging Spectrometer for Mars (CRISM), on board NASA's Mars Reconnaissance Orbiter. CRISM's primary mission is to search for signs that liquid water once existed on Mars by identifying minerals that form only in the presence of water. Molecules of water trapped in these minerals leave particular patterns in the sunlight that reflects off of them and into CRISM, which senses up to 544 "colors," or wavelengths, of light.
A team of researchers at The Johns Hopkins University Applied Physics Laboratory (APL), which built and operates the instrument, has converted the complex CRISM data into easy-to-understand composite images. "The images clearly show the distribution of certain minerals, which tells us about the planet's history," says Scott Murchie of APL, CRISM's principal investigator. "This map moves the information out of the domain of specialists and makes the very latest Mars research accessible to anyone with an interest in the planet." The online collection currently includes more than 900 observations, and more are being added as the team prepares them.
The high-resolution map can be found on the "CRISM Data Products: Viewing Features of Mars" website (http://crism-map.jhuapl.edu/) and is best viewed with Firefox 2.0, Netscape 7.2, or Internet Explorer 7.0, or better.
Visitors to the site choose from a selection of global background maps made by instruments on NASA's Viking, Mars Global Surveyor and Mars Odyssey spacecraft. They can zoom in, click on particular CRISM observations that dot the maps, and access a variety of images constructed from the 544-color data. These include versions of each observation that show the locations of water and carbon dioxide ice; iron-containing igneous minerals formed by volcanic activity or cratering; iron minerals that have been altered by oxygen in the atmosphere; and clay-like and sulfate minerals that were formed by past liquid water.
"The images provide good indication of where there are mineral signatures of volcanic deposits or past wet environments," says APL's Frank Seelos, CRISM's science operations lead. "Researchers can browse the map to identify interesting sites and then download the full data from NASA's Planetary Data System, an archive of data products from NASA planetary missions. Non-scientists can get a sense of the variety of geologic features on Mars, and the variety of processes that created them."
"This is the first time that these simplified versions of complex spectrometer data have been made easily available to both the science community and public," says Olivier Barnouin-Jha, a member of the CRISM operations team at APL. "The techniques we used were developed by scientists working on CRISM and a similar instrument, called OMEGA, on the European Space Agency's Mars Express. OMEGA's team pioneered some of the techniques that we use, and CRISM provides unprecedented resolution for an imaging spectrometer at Mars."
APL has built more than 150 spacecraft instruments over the past four decades. NASA's Jet Propulsion Laboratory, a division of the California Institute of Technology in Pasadena, Calif., manages the Mars Reconnaissance Orbiter for NASA's Science Mission Directorate, Washington. Lockheed Martin Space Systems, Denver, Colo., is the prime contractor for the project and built the spacecraft.
The Applied Physics Laboratory, a division of The Johns Hopkins University, meets critical national challenges through the innovative application of science and technology. For more information, visit http://www.jhuapl.edu. For more information on CRISM, visit http://crism.jhuapl.edu.