January 28, 2017

From LPOD
Revision as of 01:04, 28 January 2017 by Api (talk | contribs) (Created page with "__NOTOC__ =A Comet and a Butterfly= Originally published April 10, 2007 <!-- Start of content --> <div class="post" id="post-1056"> <div class="storycontent"> <p>File:Messi...")
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to: navigation, search

A Comet and a Butterfly

Originally published April 10, 2007

Messier-George-LPOD.jpg
images by George Tarsoudis, Alexandroupolis, Greece, and Clementine Map-A-Planet

The rays of Messier and Messier A are very strange. “A” is the western-most of the odd twosome, with Messier itself being the more elliptical crater on the right. The two rays from “A” stream westward in a slightly widening fan. Many people don’t realize that Messier also has rays, they are less conspicuous but equally strange - spreading to the north and south, perpendicular to “A’s” rays. George says that one ray pair is like a comet train and the other is like a butterfly. That is such a fitting description of Messier’s rays that it is the term that the scientists who duplicated them in experiments called them. The butterfly and the comet train rays are the strongest proof for the laboratory conclusion that both Messier and “A” formed from a very low angle oblique impact. The space projectile came in from the east, only 3-5° above Mare Fecunditatis. It had such a westward momentum that it made a very elongated crater (Messier) and ricocheted further west and made “A”. Such ricocheting occurs in the lab experiments, as do the telltale perpendicular rays. One feature that is not well-explained is the apparent lip of another crater sticking out to the west under Messier A. It has been suggested that the lip was a pre-existing crater that just happened to be in the way. But that violates Occam’s razer which is that the simplest solution is often the best one. Since the lip is exactly inline with Messier and A, I assume it was formed with them as part of the very oblique impact. To find out more, read the interesting article in Selenology Today issue 5.

Chuck Wood

Technical Details:
March 24, 2007 17h44m39s UT.

Related Links:
Rükl plate 48

Yesterday's LPOD: Secondary Matters

Tomorrow's LPOD: Moon Sea

George’s website
Understanding Oblique Impacts from Experiments, Observations, and Modeling by E. Pierazzo and H. J. Melosh, Annual Review of Earth and Planetary Sciences
Vol. 28: 141-167; 2000.


COMMENTS?

Register, Log in, and join in the comments.