Anorthosite, 23x

Much of the lunar crust is made of plagioclase-rich anorthosite and related rocks. All anorthosite samples returned from the moon are highly fractured as a result of their long history of impact shocks. Hence, anorthosite samples are typically small and cloudy white. White is plagioclase, brown is pyroxene, and the black specks are opaques.

Anorthosite, 51x

This is a closeup of the sample above, showing detail of the small pyroxene crystals and arrays of opaques in the plagioclase crystals. Such arrays of opaques and other minerals exsolved from the high temperature plagioclase solid solution are common in terrestrial anorthosites. Notice that larger opaque grains are clustered around the pyroxene. This clustering probably represents crystallization of trapped interstitial residual liquid, rich in Fe, Ti, and other incompatible components.

Basalt, 15x

Basalts are most extensively exposed as thick sequences of lava flows on the floors of the lunar maria. Although basalts are found elsewhere, the bulk of them occupy the floors and margins of these large impact basins. The sample here has white plagioclase, green olivine, brown pyroxene, and black opaques that are mostly Fe-Ti oxides. Because the basalts are generally younger than the anorthosites, the basalts tend to be less damaged by impact shocks.

Basalt, 28X

Closeup of the sample above, showing the distinctively plum-colored pyroxenes and olive-green olivine. Plagioclase is obviously more highly fractured than is the pyroxene and olivine.

Basalt, 41X

Closeup of the sample above, showing discrete grains of olivine, pyroxene, opaques, and plagioclase.

Highland regolith, 23x

Highland soil is rich in plagioclase fragments and plagioclase-rich breccias. Visible here are white, highly fractured plagioclase fragments (left-center, right center) and a small feldspathic breccia fragment (upper left). The medium-gray fragments are feldspathic rocks also. The irregular dark fragments scattered about (e.g., bottom center) are agglutinate grains.

Highland regolith, 52x

Large grains just left of center are agglutinates. These are composed of various kinds of particles welded together by glass produced by micrometeorite impacts. They typically contain bubbles that are thought to result from the degassing of implanted solar wind hydrogen and helium, and water produced by the reaction of implanted hydrogen with oxygen of the rock. Other grains include plagioclase-rich grains (top-right), and a clear plagioclase crystal (above and to the right of center).

Highland regolith, 64x

White glass sphere, probably representing a droplet of impact melt. Other grains are feldspathic igneous rocks and breccias.

Highland regolith, 64x

Fine-grained anorthosite fragment, with other feldspathic fragments surrounding it.

Mare regolith, 48x

Mare soil, because it is derived from dominantly basaltic rocks, has a larger proportion of mafic minerals, including fragments of olivine, pyroxene, and Fe-Ti oxides in addition to plagioclase. Green and orange glass spheres are present as well. The rough and irregular grains are agglutinates.

Mare regolith, 64x

Orange glass spheres, plum-colored pyroxenes, plagioclase cyrstals, orange glass spheres, and agglutinate grains.

Mare regolith, 52x

Rich assortment of mineral grains including clear plagioclase, pale green olivine, plum-colored pyroxene, and black Fe-Ti oxides. Two modest size breccia fragments are visible (upper left), as are many small, irregular, dull dark gray agglutinate fragments (especially top center and right).

Mare regolith, 64x

A large agglutinate particle, made of grains cemented together with micrometeorite impact glass and containing numerous vapor bubbles. Numerous mineral and polyminerallic fragments are visible, and an orange glass sphere (left center, appears black).

Breccia, 16x

This breccia fragment has a wide variety of mineral and rock fragments embedded in a fine-grained matrix composed of very finely divided minerals and glass. It represents multiple episodes of impact fragmentation and welding.

Breccia, 22X

Closer view of this breccia. The large light-colored grain in the lower left is an anorthositic rock fragment, and the brown grain on the right is a fractured pyroxene.

Breccia, 40x

Closeup of the breccia fragment showing grains of green olivine and white plagioclase (right center) and brown pyroxene (bottom right). Other fragments include monominerallic grains, fine-grained igneous rocks, and small breccia fragments.

Breccia, 50x

Noritic rock fragment is the large white and brown piece at the top, and the yellow-green piece near the center is olivine.

Breccia, 50x

Several small white-and-brown noritic rock fragments and one larger one (bottom left), and a yellowish-brown pyroxene grain (near center).

Orange soil, 64x

Orange soil is composed largely of orange volcanic glass beads that are thought to have quenched during their ballistic trajectory from a fire fountain eruption. The orange color is caused by high Ti3+ concentrations in the glass.

Orange soil, 64x

Another example of the orange soil. Only some of the beads are actually orange, others underwent partial crystallization during cooling and are black.