u/random_treasures

Alright, part 2.

First, we'll look at some more chondrites, a few polymict breccias, a few unclassifieds. Polymicts are cool because they capture multiple different lithologies that sample different depths in an asteroid. They tend to be kind of chaotic, high contrast stones. NWA 16382 is beautiful, not something I find myself saying about a lot of L chondrites.

I'll throw in a few impact melt breccias, one that looks like poop. Space loves poop jokes, true story.

Things get messy with the mesosiderites, winonaites, and IAB irons. Mesosiderites are all generated during impact events as two asteroids collide. One might have a rocky silicate surface, while the other is metal-rich. When they collide, they are both vaporized, shooting a spray of molten mixed material into space. As the molten droplets in this spray collide, cool, and recombine, they reassemble themselves into a rock, that's a chaotic mixture of metal and silicate. Winonaites are failed attempts at planetary differentiation. They got big/hot enough to start mobilizing metal, but were either disrupted early, or formed a little too late to be able to complete the job. They're rare types, but are associated with the same parent bodies as IAB irons. IAB irons themselves are very diverse, because even though they're from the same parent bodies, those bodies experienced multiple giant impacts, that mixed and created different lithologies in different places on the protoplanets. IABs are so complex that there are like 6 different subtypes, that all represent different physical regions on the same asteroid.

The Hickman is very pretty, but also very unstable, as it's got significant shreibersite/cohenite inclusions that are exposed to the surface, and got weathered pretty extensively. This stone is not long for this world, it's going to turn into a pile of rust eventually. It's really beautiful though, so I'll enjoy it while it lasts. Kinda looks like Venom.

There are a few ungrouped ataxites, Dronino and Gebel Kamil. Dronino in particular is a very weird specimen. It's an old fall that landed in a swamp, and is super nickel rich, so it rusted like crazy. You have to process all that rust away to get at the deep cores of these specimens that have not been corroded yet. As a result, you get this neat aesthetic appearance, where they kind of look similar to rocks that have been eroded by wind or water. The rust preferentially forms at boundaries between crystals, so in essence, when you strip away all the rust, you're left with a chunk of metal in the shape of the crystal structure of the taenite. It's sort of analagous to how they freeze and shatter Campos to break them along crystal boundaries, and turn them into a bunch of smaller meteorites, that are basically single crystals of metal.

NWA 13272 is WEIRD. It's an ungrouped achondrite, but chemically it aligns with L-chondrites, so it might be some kind of transitional specimen, capturing a chondrite as it's turning into an achondrite. Alternatively, it may just be an L-chondrite, that's been super-heated.

NWA 11640 is a beautiful ureilite containing some really nice olivine crystals, embedded in a pigeonite/graphite matrix. It represents the cumulate mantle material of a protoplanet that was rich in carbon. Think something like a pool of magma that slowly grows crystals that fall out of the solution, and drift towards the top, or bottom of the magma chamber. Those are cumulates, think of it something like ice crystallizing in the atmosphere, and then falling out to the ground as snow, creating fluffy piles, except this is all happening in a liquid magma chamber instead.

We end with the planetary achondrites, from the Moon, and Mars. The two lunars capture very different lithologies, from different parts of the lunar crust. The entire surface of the moon has been impact-gardened heavily for 4.5 billion years. As a result, it's been thoroughly shattered down to a depth of dozens of km. Almost everything on the moon's surface is a breccia, composed of particles that have been smashed to bits over, and over again, remelted, recombined, and smashed to bits again. It's very similar to Howardites from Vesta, actually, in a physical sense, albeit not a chemical one.

The martian meteorites are some of my favorites. There is nothing I enjoy more than dropping a piece of Mars into someone's hand, *before* telling them what it is. That wide-eyed realization of what they're holding is just priceless. Ouargla 010 is a great little piece, super aesthetic, just a killer example of a shergottite, but also very different from DAG476, the other shergottite, that formed within an extruding lava flow within ~1 meter of the surface of Mars, approximately 441 million years ago, where it sat for 440 million years before it was knocked into space by an asteroid impact. It floated through space for 1.1 million years before colliding with Libya. It sat in the Libyan desert for ~60,000 years until it was recognized as a meteorite, and collected.

Thought I'd post my meteorite collection. The other half will come tomorrow probably.

We start with the carbonaceous chondrites, which formed in the outer solar system, in the region of Jupiter and beyond. There is a stark divide between inner/outer solar system meteorites. Everything that formed past Jupiter retained large amounts of carbon. Most things that formed in the inner solar system boiled off their carbon as they heated up, allowing water to react with carbon to form CO, and CO2 gas. These then escaped the stones, and were blown out to the outer solar system, leaving most inner solar system meteorites carbon-poor.

Then we dip into the inner solar system chondrites, L, LL, H, and R chondrites. These formed in the inner solar system, and lost much of their carbon. L and LL chondrites together comprise over 90% of all known meteorites. Together, the condrites are the raw ingredients of the solar system. Petrologic grades from 1-7 are assigned to each. Grade 3 represents pristine, unaltered solar system material. Grades 2 and below represent material that was subsequently altered by water, usually because they got warm enough to melt ice. Grades 4 and above represent material that was instead altered thermally. Roughly speaking, the deeper inside the parent body they formed, the higher their petrologic grade, because the deep insides of protoplanets are warmer than their surfaces.

We'll take a quick dip into achondrites with Erg Chech 002, Djoua 001, and a ureilite. These specimens represent more evolved bodies, but still very early in the solar system. Erg Chech 002 was producing andesite lava before Vesta even figured out basalt. It was a fully differentiated, evolved protoplanet that was born within the first million years of the solar system. Djoua 001 formed near Mercury, absolutely scorched by the sun. Ureilites formed near Earth, but are weird in that they still contain carbon. They got big enough, early enough to lock carbon in their mantles before it could all be turned to gas and vented to space.

Next, we look at the HED group, and sample specimens from 4-Vesta, the howardites, eucrites, and diogenites. These respectively represent the surface, magmatic crust, and mantle layers of the second largest asteroid, 4-Vesta. Jikharra 001 in particular is just a ridiculous specimen. Meteorites don't usually contain bubbles, this one has so many it's almost rock-foam. There aren't even words for how cool this specimen is.

We end today by dipping into irons, and pallasites that represent the cores, core/mantle boundaries, or highly metal-rich regions of protoplanets that are all dead now.

I love this little guy. It's a significant upgrade from my previous 0.27g of Mars (DAG476). One of my favorite things to do when giving tours of my museum is to drop a piece of Mars into someone's hand, before telling them what it is. It never fails to get a reaction, but it's always been a little unsatisfying for it to be a tiny chip that we're both afraid is going to get broken.

It's an olivine microgabbroic shergottite. I think what that means is that it formed in a magma, cooled underground at medium depth of several km, and never erupted onto the surface. If it had formed deeper, the olivine crystals would be larger. If it formed closer to the surface, they would be smaller. There's something cool about being able to determine the conditions a rock formed under, a billion years ago, on a different planet.

The orange crystals are shocked olivine, while the black crystals are feldspar that was shock-converted to maskelynite.

I'm very curious about that CAI, it's by far the largest in any of my meteorites, and seems to have spinel inclusions inside it?

I'd love to find out what the black chondrule on the top right is. Visually, it sort of stands out in opposition to the white CAI.