On August 6, 2012, Curiosity (the
Mars Science Laboratory rover) landed in "Yellowknife" Quad 51[3][4][5][6] of
Aeolis Palus,[7] next to the mountain. NASA named the landing site
Bradbury Landing on August 22, 2012.[8] Aeolis Mons is a primary goal for scientific study.[9] On June 5, 2013, NASA announced that Curiosity would begin an 8 km (5.0 mi) journey from the
Glenelg area to the base of Aeolis Mons. On November 13, 2013, NASA announced that an entryway the rover would traverse on its way to Aeolis Mons was to be named "Murray Buttes", in honor of
planetary scientistBruce C. Murray (1931–2013).[10] The trip was expected to take about a year and would include stops along the way to study the local terrain.[11][12][13]
On September 11, 2014, NASA announced that Curiosity had reached Aeolis Mons, the rover mission's long-term prime destination.[14][15] Possible
recurrent slope lineae, wet
brine flows, were reported on Mount Sharp near Curiosity in 2015.[16] In June 2017, NASA reported that an ancient
striated lake had existed in Gale crater that could have been favorable for
microbial life.[17][18][19]
Formation
The mountain appears to be an enormous mound of eroded sedimentary layers sitting on the central peak of Gale. It rises 5.5 km (18,000 ft) above the northern crater floor and 4.5 km (15,000 ft) above the southern crater floor, higher than the southern crater rim. The sediments may have been laid down over an interval of 2 billion years,[20] and may have once completely filled the crater. Some of the lower sediment layers may have originally been deposited on a lake bed,[20] while observations of possibly cross-bedded strata in the upper mound suggest
aeolian processes.[21] However, this issue is debated,[22][23] and the origin of the lower layers remains unclear.[21] If
katabatic wind deposition played the predominant role in the emplacement of the sediments, as suggested by reported 3 degree radial slopes of the mound's layers, erosion would have come into play largely to place an upper limit on the mound's growth.[24][25]
On December 8, 2014, a panel of NASA scientists discussed (
archive 62:03) the latest observations of Curiosity about how water may have helped shape the landscape of Mars, including Aeolis Mons, and had a climate long ago that could have produced long-lasting lakes at many Martian locations.[26][27][28]
On October 8, 2015, NASA confirmed that lakes and streams existed in Gale crater 3.3 - 3.8 billion years ago delivering sediments to build up the lower layers of Mount Sharp.[29][30]
On February 1, 2019, NASA scientists
reported that Curiosity had determined, for the first time, the density of Mount Sharp in Gale crater, thereby establishing a clearer understanding of how the mountain was formed.[31][32]
In comparison,
Mount Everest rises to 8.8 km (29,000 ft) altitude above sea level (asl), but is only
4.6 km (15,000 ft) (base-to-peak) (btp).[34] Africa's
Mount Kilimanjaro is about 5.9 km (19,000 ft) altitude above sea level to the Uhuru peak;[35] also 4.6 km base-to-peak.[36] America's
Denali, also known as Mount McKinley, has a base-to-peak of 5.5 km (18,000 ft).[37]
The Franco-Italian Mont Blanc/Monte Bianco is 4.8 km (16,000 ft) in altitude above sea level,[38][39]Mount Fuji, which overlooks Tokyo, Japan, is about 3.8 km (12,000 ft) altitude. Compared to the
Andes, Aeolis Mons would rank outside the hundred tallest peaks, being roughly the same height as Argentina's
Cerro Pajonal; the peak is higher than any above sea level in Oceania, but base-to peak it is considerably shorter than Hawaii's
Mauna Kea and
its neighbors.
Name
Discovered in the 1970s,[citation needed] the mountain remained unnamed for several decades. When Gale crater became a candidate landing site, the mountain was given various labels e.g. in 2010 a NASA photo caption called it "Gale crater mound".[40] In March 2012, NASA unofficially named it "Mount Sharp", after American geologist
Robert P. Sharp.[1][41]
Since 1919 the
International Astronomical Union (IAU) has been the official body responsible for
planetary nomenclature. Under its long-established
rules for naming features on Mars, mountains are named after the
classical albedo feature in which they are located, not after people. In May 2012 the IAU officially named the mountain Aeolis Mons after the
Aeolis albedo feature.[42] It also gave the name
Aeolis Palus to the plain located on the crater floor between the northern wall of Gale and the northern foothills of the mountain.[1][43][44][45] The IAU's choice of name is supported by the
United States Geological Survey.[44] Martian craters are named after deceased scientists, so in recognition of NASA and Sharp, at the same time the IAU named "
Robert Sharp", a large crater (150 km (93 mi) diameter) located about 260 km (160 mi) west of Gale.[46]
NASA and the
European Space Agency[47] continue to refer to the mountain as "Mount Sharp" in press conferences and press releases. This is similar to their use of other informal names, such as the
Columbia Hills near one of the
Mars Exploration Rover landing sites.
In August 2012, the magazine Sky & Telescope ran an article explaining the rationale of the two names and held an informal poll to determine which one was preferred by their readers. Over 2700 people voted, with Aeolis Mons winning by 57% to Mount Sharp's 43%.[41]
Geology map – from the crater floor in
Aeolis Palus up the slopes of Aeolis Mons (September 11, 2014).
Rocks in "Hidden Valley" near the "Pahrump Hills" on the slopes of Aeolis Mons as viewed from Curiosity (September 11, 2014;
white balanced).
On December 16, 2014, NASA reported detecting, based on measurements by the Curiosity rover, an unusual increase, then decrease, in the amounts of
methane in the
atmosphere of the planet Mars; as well as, detecting Martian
organic chemicals in powder drilled from a
rock by the rover. Also, based on
deuterium to
hydrogen ratio studies, much of the
water at Gale Crater on Mars was found to have been lost during ancient times, before the lakebed in the crater was formed; afterwards, large amounts of water continued to be lost.[48][49][50]
On June 1, 2017, NASA reported that the Curiosity rover provided evidence of an ancient lake in Gale crater on Mars that could have been favorable for
microbial life; the ancient lake was
stratified, with shallows rich in
oxidants and depths poor in oxidants; and, the ancient lake provided many different types of microbe-friendly environments at the same time. NASA further reported that the
Curiosity rover will continue to explore higher and younger layers of Mount Sharp in order to determine how the lake environment in ancient times on Mars became the drier environment in more modern times.[17][18][19]
On April 11, 2019, NASA announced that Curiosity had drilled into, and closely studied, a "
clay-bearing unit" which, according to the rover Project Manager, is a "major milestone" in Curiosity's journey up Mount Sharp.[53]
In January 2023, Curiosity viewed and studied the "Cacao" meteorite.
In August 2023, Curiosity explored the upper
Gediz Vallis Ridge.[54][55] A panoramic view of the ridge is
here, and a 3D rendered view is
here.
Self-portrait of Curiosity at the Mojave site (January 31, 2015).
As of April 26, 2024, Curiosity has been on the planet Mars for 4167
sols (4281
total days) since landing on August 6, 2012. Since September 11, 2014, Curiosity has been
exploring the slopes of
Mount Sharp,[14][15] where more information about the
history of Mars is expected to be found.[56] As of January 26, 2021, the rover has traveled over 24.15 km (15.01 mi) and climbed over 327 m (1,073 ft) in elevation[57][58][59] to, and around, the mountain base since landing at "
Bradbury Landing" in August 2012.[57][58]
Layers at the base of Aeolis Mons - dark rock in inset is same size as Curiosity (
white balanced image).
Curiosity'swheels - Aeolis Mons is in the background (
MAHLI, September 9, 2012).
First-Year and First-Mile
Traverse Map of the Curiosity rover on Mars (August 1, 2013) (
3-D).
Curiosity (in rectangle) in the Pahrump Hills of Mount Sharp – as viewed from space (
MRO;
HiRISE; December 13, 2014).
Curiosity rover (center bright blue) on Mount Sharp viewed from orbit (
MRO;
HiRISE; June 5, 2017).[61]
Curiosity's view of the "
Rocknest" area – South is center/North at both ends; "Mount Sharp" at SE horizon (somewhat left-of-center); "
Glenelg" at East (left-of-center); rover tracks at West (right-of-center) (November 16, 2012;
white balanced) (
raw color) (
interactives).
Curiosity's view of "Amargosa Valley" on the slopes of "Mount Sharp" (September 11, 2014;
white balanced image).
Curiosity's southward-looking view on the slopes of "Mount Sharp" (April 11, 2015).[62]
Curiosity's view near "Logan Pass" on the slopes of "Mount Sharp" (May 10, 2015;
white balanced image).
^
ab
Anderson, R. B.; Bell III, J. F. (2010). "Geologic mapping and characterization of Gale Crater and implications for its potential as a Mars Science Laboratory landing site". International Journal of Mars Science and Exploration. 5: 76–128.
Bibcode:
2010IJMSE...5...76A.
doi:
10.1555/mars.2010.0004.
^Adam Helman, 2005. The Finest Peaks : Prominence and Other Mountain Measures, p. 9: "the base to peak rise of Mount McKinley is the largest of any mountain that lies entirely above sea level, some 18000 feet"