03.21.2017 Break in Raised Tread on Curiosity Wheel
03.17.2017 COBALT/JPL team
03.09.2017 Back-to-Back Martian Dust Storms
02.27.2017 Swirling Dust in Gale Crater, Mars, Sol 1613
02.27.2017 Dust Devil Passes Near Martian Sand Dune
02.27.2017 Sand Moving Under Curiosity, One Day to Next
02.08.2017 Mars Reconnaissance Orbiter Observes Changes
01.26.2017 Mono Lake
01.25.2017 'Wing' Dike of Hardened Lava in New Mexico
01.25.2017 Blade-Like Martian Walls Outline Polygons
01.23.2017 Spirit And Opportunity By The Numbers
01.10.2017 Mars 2020 Rover - Artist's Concept
01.06.2017 Earth and Its Moon, as Seen From Mars
12.13.2016 Now and Long Ago at Gale Crater, Mars
12.13.2016 Where's Boron? Mars Rover Detects It
11.15.2016 Schiaparelli Impact Site on Mars, Stereo
11.03.2016 Schiaparelli Impact Site on Mars, in Color
10.17.2016 MAVEN Captures Rapid Cloud Formation
10.17.2016 Mars' Nightside Atmosphere
10.17.2016 Ultraviolet Image Near Mars' South Pole
10.17.2016 Ultraviolet Mars Reveals Cloud Formation
10.05.2016 Dust Haze Hiding the Martian Surface in 2001
10.04.2016 Test of Lander Vision System for Mars 2020
10.03.2016 A Sharpened Ultraviolet View of Mars
10.03.2016 Curiosity Self-Portrait at 'Murray Buttes'
10.03.2016 Butte 'M9a' in 'Murray Buttes' on Mars
09.19.2016 Ribbon Cutting
09.09.2016 Farewell to Murray Buttes (Image 5)
09.09.2016 Farewell to Murray Buttes (Image 4)
09.09.2016 Farewell to Murray Buttes (Image 3)
09.09.2016 Farewell to Murray Buttes (Image 2)
09.09.2016 Farewell to Murray Buttes (Image 1)
08.26.2016 Out-of-this-World Records
08.04.2016 Mars Rover Is New Social Media Game
08.04.2016 Mars Rover Social Media Game
08.02.2016 Artist Concept for RIMFAX
Clay Minerals in Craters and Escarpments on MarsImpact cratering and erosion combine to reveal the composition of the Martian underground by exposing materials from the subsurface. Investigation of exposed clay minerals at thousands of Martian sites by the Compact Reconnaissance Imaging Spectrometer for Mars (CRISM) on NASA's Mars Reconnaissance Orbiter suggests a long period of wet, warm conditions, mostly underground.
Infrared light indicates terrains of different composition in false-color infrared images (top) of a crater (left) and an escarpment (right). Each of the scenes is about 6 miles (10 kilometers) wide. The lower images of the same sites show how distinctive absorption bands permit identification and mapping of specific minerals. In the lower images, iron-magnesium clays are mapped in blue. These are the most common clays on Mars, occupying large sections of the deep crust and mostly formed by subsurface water. These clays are beneath unaltered volcanic layers that contain the mineral olivine (green). The site shown in the image on the right also contains aluminum clays (red), which formed by waters near the surface. These clays are uncommon on Mars but are sometimes located on top of iron-magnesium clays in a distinctive stratigraphy, indicating formation later in time.
These two example sites, out of thousands where CRISM has observed clay minerals, are at 10.65 degrees south latitude, 98.22 degrees east longitude (left pair) and 22.06 degrees north latitude, 74.63 degrees east latitude (right pair).
In the top two images, the false color comes from presenting observed brightnesses in three different wavelengths of invisible infrared wavelengths -- 2,529 nanometers, 1,506 nanometers and 1,080 nanometers -- as red, green and blue, respectively, composited into color images.
In the bottom two images, colors are assigned to absorption-band characteristics: infrared frequencies at which the materials on the Mars surface are less bright compared to their brightness at other frequencies. The data presented as red are pixel-by-pixel absorption-band depths at 2,210 nanometers, the data presented as green are broad absorption-band depths near 1,000 nanometers, and the data presented as blue are the absorption-band depths at 2,300 nanometers. These color data were then overlain and merged with the brightness at 770 nanometers to show the relationship of detected minerals with underlying topography. For more information on mineral mapping and more CRISM images, see http://crism-map.jhuapl.edu .
NASA's Jet Propulsion Laboratory, a division of the California Institute of Technology, Pasadena, manages the Mars Reconnaissance Orbiter for the NASA Science Mission Directorate, Washington. Lockheed Martin Space Systems, Denver, built the spacecraft. The Johns Hopkins University Applied Physics Laboratory led the effort to build the CRISM instrument and operates CRISM in coordination with an international team of researchers from universities, government and the private sector.
Image Credit: NASA/JPL-Caltech/JHUAPL