A Colorful History of Floor-Fractured Komarov

A small, fresh crater dots the wall of a fracture in the floor of Komarov crater. Image taken from LROC NAC frame M130653607. Image width is approximately 2.5 km [NASA/GSFC/Arizona State University].

A small, fresh crater can be seen on the right side of Today's Featured Image on the floor of Komarov crater. The crater was formed when an impactor smashed into the wall of one of the fractures (or graben) in the crater floor. Some of the ejecta from the impact can be seen draping the wall of the graben. This graben is one of many in the floor of Komarov.

LROC WAC context image of Komarov crater (~80 km in diameter). Image is centered at 24.586°N, 152.248°E. The full NAC frame is denoted by the red box, whereas Today's Featured Image is indicated by the yellow box [NASA/GSFC/Arizona State University].

Komarov, best seen in the context image above, is known as a floor-fractured crater whose fractures likely formed through intrusive magmatic activity. The western portion of Komarov crater has been modified by the deposition of smooth, low albedo material and the formation of floor fractures. Is this the same low albedo mare basalts that filled nearby Mare Moscoviense?

LROC WAC context image of Komarov crater (~80 km in diameter) relative to Mare Moscoviense (centered at 27.282°N, 148.122°E). The red box denotes the full NAC frame from which Today's Featured Image was taken. Image is ~450 km wide [NASA/GSFC/Arizona State University].

Though Komarov is located on the edge of Mare Moscoviense, it is not covered in the same smooth, low albedo mare basalts that are seen in the Moscoviense basin today (See WAC context image above and Clementine false-color image below). Compositional differences in and around Mare Moscoviense indicate multiple episodes of volcanic activity. Three bands (415 nm, 750 nm, and 1000 nm) from the Clementine UVVIS camera were used to create the false-color image below. The three bands were ratioed to control the colors of the false-color image. The 750/415 ratio controls the red component, which is an indication of low titanium or high glass content as found in mature lunar regolith and to a greater degree pyroclastic deposits. The 750/1000 ratio controls the green component and is an indicator of the amount of iron on the surface. The 415/750 ratio controls the blue component and indicates high titanium or bright slopes and albedos.

Clementine false-color image of Komarov crater and Mare Moscoviense. The dashed circle indicates the rim of Komarov. The white arrow points to a fresh crater from the full NAC frame. Image is approximately 180 km across [NASA/USGS/Arizona State University].

Notice in the false-color image above that Mare Moscoviense appears blue (higher in titanium since we know Mare Moscoviense is a low albedo feature), whereas Komarov appears red. Even within Komarov, the western side is more red (likely pyroclastics or low-titanium basalts) than the eastern side, which is comparable to deep red of the surrounding highlands (mature regolith). A crater in the NAC frame from which Today's Featured Image was taken appears bright blue and stands out from the rest of Komarov's floor. This bright blue color is likely due to the fact that this crater is fresh and has brought up unweathered (fresh) higher albedo material from depth. The fresh crater from the opening image is too small to be seen in the Clementine false-color image.

Investigate this complex region for yourself below!

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Posted by H. Meyer on January 23, 2014 08:00 UTC.