How and When The 4.5 Billion-Year-Old ALH84001 Martian Meteorite Was Found


  ALH 84001 was found in Antarctica during the 1984-1985 Antarctic summers. It was found by a team of meteorite hunters from the ANSMET program, which is sponsored by the Polar Programs Office of the U.S. National Science Foundation.

ANSMET stands for ANtarctic Search for METeorites, and has been funded since 1977 by the NSF. In that time, ANSMET meteorite hunters have found more than 7,000 meteorites. The Antarctic Meteorite Location and Mapping Project (AMLAMP) provides locations, maps, and databases for meteorite finds.


Martian meteorite ALH 84001 at Johnson Space Center, after being returned from Antarctica. For scale, the black cube is 1 cm on each side. The outside of ALH 84001 is partially coated with black fusion crust caused by entering Earth's atmosphere. The interior is a uniform greenish-gray.
ALH 84001 formed about 4.5 billion years ago in a relatively large magma body inside the crust of Mars. Its high abundance of one mineral (orthopyroxene)  indicates that this mineral must have accumulated in the magma, probably near the bottom of the magma body, eventually forming the original igneous rock with large crystals of orthopyroxene.                                                                                                                                   
Large crystals of orthopyroxene in ALH 84001 show that this rock formed in an underground magma chamber on Mars. Dark areas are chromite (an oxide of chromium and iron).  

Of the 24,000 or so meteorites that have been discovered on Earth, only 34 have been identified as originating from the planet Mars. Of the 34 Martian meteorites, 15 have been found in Antarctica.

These rare  meteorites created a stir throughout the world when NASA announced in August 1996 that evidence of microfossils may be present in one of these Mars meteorites.
What they found inside ALH8001
Birthplace Of Alh8400:
Eos Chasma, Part Of Valles Marineris
These images, taken by the High Resolution Stereo Camera (HRSC) on board ESA's Mars Express spacecraft, show the southern part of Valles Marineris, called Eos Chasma. The images were taken during orbit 533 in June 2004, and are centered at Mars longitude 322° East and latitude 11° South. The image resolution is approximately 80 meters per pixel.


Between surrounding plains and the smooth valley floor, a height difference of about 5000 meters has been measured. The plain to the south, above Eos Chasma, is covered by several impact craters with diameters of around 20 kilometers and drainage channels.

Source: ESA/DLR/FU Berlin (G. Neukum) and NASA/MSSS/RPIF/DLR - http://berlinadmin.dlr.de/Missions/express/first/30.08.2004_eng.shtml
Source Region Discover for ALH84001
The original home of the world's most famous space rock, the Allen Hills Martian meteorite, has now been identified, thanks to data from the orbiting spacecrafts, Mars Global Surveyor and Mars Odyssey, along with a better understanding of cratering dynamics.

The rock, called ALH84001, has been the subject of intense study ever since 1996 when scientists from NASA's Johnson Space Center startled the world by reporting that fossilized microbial life might be embedded inside. The rock, which formed at the very dawn of the solar system 4.5 billion years ago, was blasted from the surface of Mars around 17 million years ago by an impact and made its way to Earth, landing in Antarctica.  While the claim remains highly controversial, the JSC scientists say further study has bolstered the evidence for fossilised life in ALH84001. So the discovery of the rock's place of origin on Mars could make that spot a strong candidate for a future landing by robots or people searching for extraterrestrial life.

The analysis, based on the rock's mineral characteristics, was presented by Vicky Hamilton of the University of Hawaii at this week's meeting of the Meteoritical Society in Tennessee, US.

Hamilton looked for matches between the laboratory spectrum of the meteorite, a mix of orthopyroxene and basaltic minerals, and data from the Thermal Emission Spectrometer and other instruments on the orbiters. "There was only this one place, in all the places we can look that aren't too dusty, that had a composition that was consistent with the ALH84001," Hamilton told New Scientist.

The site is in the Eos Chasma, a branch of the enormous Valles Marineris canyon system. Hamilton has examined it further using topographic and thermal data and high-resolution imagery. "Putting this all together, it's all consistent with this being the source region," she said.
The pinpointed area is a "lobate flow", the kind that occurs when an impacting object strikes a fluid-rich soil, as is the case with many Martian craters. There is a crater about 20 kilometres in diameter there, which cratering studies have now shown indicates a large enough impact to eject the rock out of Mars' gravitational field.

There is no single "smoking gun" piece of evidence that proves this was the place the meteorite came from, Hamilton concedes: "There isn't any piece of information that makes this a unique interpretation, other than the fact that we haven't seen any other suitable places."

Source: David L Chandler at NewScientist.com news service - http://www.newscientist.com/article.ns?id=dn8004
Kristie Mamelli
kmamelli @ gmail.com
Department of Geography
California State University
Long Beach, CA 90840
(562) 985-8432