On 6 June, the high-resolution stereo camera on
ESA’s Mars Express revisited the Argyre basin as featured in our October
release, but this time aiming at Nereidum Montes, some 380 km northeast of
Hooke crater.
The stunning rugged terrain of Nereidum
Montes marks the far northern extent of Argyre, one of the largest impact
basins on Mars. Nereidum Montes stretches almost 1150 km and was named by the
noted Greek astronomer Eugène Michel Antoniadi (1870–1944).
Based on his extensive observations of Mars,
Antoniadi famously concluded that the ‘canals’ on Mars reported by Percival
Lowell were, in fact, just an optical illusion.
Nereidum Montes perspective view
The images captured by Mars Express show a
portion of the region, displaying multiple fluvial, glacial and wind-driven
features. Extensive dendritic drainage patterns, seen towards the north (lower
right side) of the first and topographic images, were formed when liquid water
drained into deeper regions within the area.
On Earth, tree-like channels of this kind are
usually formed by surface runoff after significant rainfall, or when snow or
ice melts. Similar processes are thought to have occurred on Mars in the
distant past, when scientists now know there to have been water on the surface
of the Red Planet.
Several of the craters within the region,
particularly in eastern parts (lower section) of the first image, show
concentric crater fill, a distinctive martian process
marked by rings of surface fluctuations within a crater rim.
The ratios between the diameter and depth of
the filled craters suggest that there may still be water ice, possibly in the
form of ancient glaciers, present below the dry surface debris cover.
Nereidum Montes in context
Scientists have estimated that the water-ice
depth in these craters varies from several tens up to hundreds of metres. The
largest crater on the south western side (top-left half) of the first and
topographic images appears to have spilled out a glacier-like formation towards
lower-lying parts of the region (shown as blue in the topographic image).
Topographical view
A smooth area to the east of (below) the
glacial feature appears to be the youngest within the image, evidenced by an
almost complete lack of cratering.
Another indication of subsurface water is
seen in the fluidised ejecta blanket surrounding the crater at the northern
edge (right-hand side) of the first and topographic images. These ejecta
structures can develop when a comet or asteroid hits a surface saturated with
water or water ice.
Perspective view
Finally, throughout the images and often near
the wind-sheltered sides of mounds and canyons, extensive rippling sand dune
fields are seen to have formed.
3D view
In-depth studies of regions such as Nereidum
Montes play an essential role in unlocking the geological past of our terrestrial
neighbour, as well as helping to find exciting regions for future robotic and
human explorers to visit.
For further information visit: http://www.esa.int/esaCP/SEMO3S52Q8H_index_0.html
No comments:
Post a Comment