and now on its way to me from Germany. I told my wife today: “Retail therapy” is a process, not a destination. 🙂

This is one of only 12 meteorites that are classified as diogenite-olivine or harzburgitic — greater than 40% olivine and the orthopyroxene is magnesian in contrast to conventional ferroan orthopyroxene diogenites.

NWA 7370 is also quite high in chromite (15 wt%). Chromite can be seen as black notches protruding from the crust. Due to its higher melting point, the chromite resisted atmospheric ablation better than the matrix.

Write up (Meteoritical Bulletin 101):

History: Four meteorites were discovered by an anonymous finder east of Agaraktem, Mali, in May 2009.

Classification: Olivine diogenite, S1, very fresh with remains of fusion crust and some partially ablated chromite grains.

With its well-preserved texture, bottle-green matrix and olive drab patina this rare HED achondrite is quite a beauty.

426g, 83 x 60 x 40 mm (3.3″ across)

3 responses to “A Green Rock from Deep Inside Asteroid Vesta — Main Mass of NWA 7370”

  1. jurvetson Avatar
    jurvetson

    the far-face

    Reply
  2. andershjemdahl Avatar
    andershjemdahl

    Absolutely incredible!

    That’s some high quality retail therapy!

    Reply
  3. jurvetson Avatar
    jurvetson

    Diogenite comes from deep in the mantle of Vesta, We have never drilled that deep on Earth, but it might look somewhat similar. New work on exposed mantle in Maryland give us a sense of what it looks like. From National Geographic:

    "While this layer of rock is usually found between the planet’s crust and core, a segment peeks out of the scrubby Maryland forest, offering scientists a rare chance to study Earth’s innards up close. Even more intriguing, the rock’s unusual chemical makeup suggests that this piece of mantle, along with chunks of lower crust scattered around Baltimore, was once part of the seafloor of a now-vanished ocean.
    Over the roughly 490 million years since their formation, these hunks of Earth were smashed by shifting tectonic plates and broiled by searing hot fluids rushing through cracks, altering both their composition and sheen. Mantle rock is generally full of sparkly green crystals of the mineral olivine, but the rock in my hand was surprisingly unremarkable to look at: mottled yellow-brown stone occasionally flecked with black.
    “Those rocks have had a tough life,” says George Guice, a mineralogist at the Smithsonian’s National Museum of Natural History.

    THE LURE OF GREEN SPARKLE
    Guice has long chased after sparkly green rocks, known to geologists as ultramafic. They’re rich in magnesium and make up the majority of our planet as the mantle. But pieces of the mantle are rare at the surface, and ultramafic rocks can form in several different ways, including in large crystallizing magma chambers. They’re also devilishly difficult to study.

    Ultramafic rocks form deep underground at high temperatures and pressures, so their minerals are not stable near Earth’s surface. In this shallow environment, they’re often exposed to hot fluids rushing through cracks, transforming their mineral makeup, as seen in the rocks strewn around Baltimore. Understanding the rock’s history through these changes, Guice says, is like looking through thick fog."

    Meteorites offer a preserved time capsule from these depths, albeit from an alien world.

    Reply

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