Earliest possible New Moon captured on camera

The earliest New Moon, captured at the very official instant Tuesday morning, July 8 from Elancourt, France. Inconsistencies in the line of directly reflected sunlight from the Moon's limb is a result of elevation differences, between valley and mountains illuminated at 180° phase [used with permission - Thierry Legault].

Utilizing a Takahashi FSQ-106ED with focal reducer, on a Losmandy Titan equatorial mount, captured with a IDS 3370 monochrome camera (with 2048x2048 CCD), a 850 nm low-pass filter and the NASA JPL Horizon ephemeris, Thierry Legault has broken his own previously held world record in photographing a New Moon from Earth, the most slight crescent Moon yet photographed from Earth's surface.

Not counting the more rare solar eclipse, when the Moon's profile is, quite unmistakable, starkly blocking the disk of the Sun as it passes in its orbit directly through our line of sight, the Moon is usually invisible to the naked eye (and as dangerous to the human eye) at those precise moments when a New Moon occurs.

"From the shooting site," at Elancourt, west-southwest of Versailles, in France, as Thierry posts on his website, "the angular separation between the Moon and the Sun was only 4.4 degrees" of arc (or nine solar diameters). "At this very small separation the Moon's crescent is extremely thin," only a few arc seconds of degree at its maximum, "and, above all, it is drowned in the solar glare, the blue sky being about 400 times brighter than the crescent itself," in the infrared band, "and probably" more than 1000 times brighter in the visible light spectrum. "In order to reduce the glare, the images have been taken in close infrared and a pierced screen, placed just in front of the telescope to prevents sunlight from directly entering the telescope."

View the particulars, HERE.

Twin mare pit craters in the Lake of Death

Layers of terrain, the foundation under the heavily gardened upper surface of Lacus Mortis, "the Lake of Death," hints this feature, averaging 228 meters across, was, or is, a "pit crater," closely related to similar structures (discovered in the 21st century) near the Marius Hills, in Mare Tranquillitatis, Mare Ingenii and elsewhere. Though the east wall collapsed there may yet be an opening below a ledge. LROC Narrow Angle Camera (NAC) observation M126759036L, orbit 3814, April 24, 2010; 49.4° angle of incidence, resolution 0.5 meters from 45.56 km [NASA/GSFC/Arizona State University].

Joel Raupe
Lunar Pioneer

It was something of a sensation just a few years ago when Kaguya (SELENE-1) images unveiled a "pit crater," an honest to goodness opening into a sublunarean world.

Ant this new feature was found right in the middle of the long-observed and studied channel of the unofficially named "Sinuous Rille A," in the Marius Hills of Oceanus Procellarum. What a difference, many thought, high resolution photography would make of our knowledge of the lunar surface.

And they were not disappointed. Most of what we now know of the lunar surface is entirely a product of the 21st century, largely a pay off from "precursor" missions vital to the success of a now-scrubbed program ahead of a return to the surface of "extended human activity" later this decade.

Junichi Haruyama and his colleagues reported their findings in Geophysical Research Letters in 2009, having captured the Marius Hills Pit at resolutions as high as 6 meters per pixel using the Kaguya Terrain Camera and Multiband Imager, as discussed by LROC principle investigator Marc Robinson, March 1, 2010.

The same partially collapsed, or filled-in, pit crater in the Rimae Burg region of Lacus Mortis (44.96°N, 25.62°E), from an oblique LROC NAC mosiac M1105701957LR, with spacecraft slewed -41.94° off nadir, orbit 15246, October 24, 2012; 59.78° incidence angle, 2 meters resolution from 155.54 km over 44.92°N, 25.52°E. Explore a full-resolution version HERE [NASA/GSFC/Arizona State University].

Not many months after the controlled impact of Kaguya the Lunar Reconnaissance Orbiter began its long and productive tour in lunar orbit.

Early in that still-ongoing mission the LROC team at Arizona State University released their own high-resolution NAC images of the Marius Hills Pit, and under a variety of lighting angles, while announcing the discovery of two additional, even larger and more distinctive "pits" in the western interior of Mare Ingenii and the well-preserved example near Sinas J, not far from the vent structures at the west terminus of Rupes Cauchy, in the middle of Mare Tranquillitatis.

These new images left little doubt that significant underground areas existed on the Moon, though how far these sublunarean areas stretched beyond their exposed "skylights," the true scope of the Moon's near-surface underground world, must remain a mystery for some time to come.

For a while mare pit craters seemed to be solitary creatures, all alone where they have now been extensively photographed. But the partially filled examples in Lacus Mortis might be near "twins." The 250 meter-wide pit crater above is only 9.7 km southwest of its neighbor (in the first image above - a 13 km walk) from 44.80857°N, 25.21157°E. The view above is from a kilometer-wide field of view from LROC NAC mosaic M122041942LR, orbit 3119, March 1, 2010; 0.5 meters resolution from 46.11 km. (Download the very large original mosaic HERE) [NASA/GSFC/Arizona State University].

These features seemed to be rare and solitary. Rough treatment of the lunar surface, aeons of steady and sometimes heavy bombardment seemed to leave very few of these openings intact. Perhaps the same may be true of extended "lava tubes," and other tantalizing, hoped-for discoveries.

Planetary scientists and geologists have studied the interior walls of these structures. The LROC team has released a high volume of imagery of the Tranquillitatis pit crater, for example, and attempts have been made to map the history of lava inundations recorded in the exposed layers.

Following discovery of three, widely dispersed pit craters at Marius, Tranquillitatis and Ingenii, at least two more smaller and much less distinct examples have turned up Mare Fecunditatis and Mare Smythii.

The unique Natural Bridge feature of King Y is a nearly unique example of the much more widespread family of collapse and channel remnants common to impact melts, both inside and outside relatively "recent" impacts, like the northeast quadrant of the interior of Copernicus, for example, and deep inside Messier A. To distinguish these from the Marius-Tranquillitatis-Ingenii family of openings, the latter are now referred to as mare pit craters.

Far from being as widespread as melt channels and collapse pit, the Mare Pit Craters seemed to be solitary, perhaps one to a plain, if any at all. As seems common to all deep space discoveries, however, of course there had to be an exception.

"Twin" Mare Pit Craters, roughly 10 km apart (as the LM ascent stage flies) on opposite sides of the primary channel in the Rimae Burg region, west-central Lacus Mortis. This field of view is 15.72 km across, from LROC MAC mosaic M1105701957LR [NASA/GSFC/Arizona State University].

In the west central interior of the rugged Lacus Mortis plain are two near-quarter kilometer-wide pits, though both are either partially or completely filled in. They are intriguingly situated on opposite sides of a main channel north of its junction with a distinctive faulting in the Rimae Burg vicinity, northeast of the volcanoes highlighted in an LROC Featured Image (Volcanoes in the Lake of Death), August 11, 2010.

Lacus Mortis, from the LROC web-based PDS search tool, showing the prior image field of view outlined by a white rectangle. Note the concurrence with a junction zone of the fault and channel constituents of Rimae Burg [NASA/GSFC/Arizona State University].

The interior walls of the northeastern twin, shown in the first two images above, retains the kind of layering seen in the Tranquillitatis and Ingenii pits, evidence of periodic lava flooding in the remote past. This bedrock under Lacus Mortis makes for a tough roof, but over what? Have any of these mare pit craters yet been found over the deeper basins?

The east-southeast wall of the northeast pit seems to have filled in, like a forgotten entrance to a pharaoh's tomb, though the south interior stays in hard shadow at this latitude. But the north wall offers up a shadow ring where the sun's angle should be well placed for illumination, hinting at an unseen and deeper interior perhaps.

The perspective from Earth, the area of interest marked by a bright asterisk in west central Lacus Mortis, an eyebrow for the "Man in the Moon" (yellow rectangle in inset). From a First Quarter Moon montage captured April 21, 2010. Photo by Yuri Goryachko, Mikhail Abgarian, Konstantin Mororzov - ASTRONOMINSK, Minsk, Belarus.

Sadly, the southeastern twin, though apparently the "real deal," appears very degraded. Exterior regolith, heavily pounded by the steady bombardment of the micrometeorites gardening the upper three centimeters of the lunar surface every two million years, has spilled over filled the interior. Its south wall, in high latitude shadow, stays invisible in shadow, but with little visible component leading to an indication of any difference with the rest of its fine-grained interior fill.

Did these two examples of mare pit craters, perhaps the only such "twins" on the Moon, degrade more quickly because of a greater age than their more noted cousins at Tranquillitatis or Ingenii? Did the arrival of the impact that formed Burg cave them in? Is this area more prone to Moonquakes?

Related Posts:
Pit Crater in Fecunditatis (May 23, 2013)

Copernicus Collapse Pit (March 5, 2013)

Melt pit on the floor of Louville D (August 16, 2012)
Impact melt collapse pit (March 2, 2012)
Failed Skylights of Copernicus (January 24, 2012)
New view of Sinas pit crater (November 11, 2011)

Layering in Messier A (July 22, 2011)
Sublunarean Void (February 8, 2011)
New views of lunar pits (September 14, 2010)

Natural Bridge on the Moon (September 7, 2010)
Depths of Mare Ingenii (June 16, 2010)
How common are mare pit craters? (July 15, 2010)

Haruyama Cavern in the Marius Hills (March 2, 2010)

Paul Spudis: Caves on the Moon (October 28, 2009)

Tsiolkovskiy central peaks at sunset

LROC Narrow Angle Camera (NAC) oblique view of the central peaks of Tsiolkovskiy. (See the full-size mosaic assembled HERE.) LROC Narrow Angle Camera (NAC) mosaic M1111030948LR, from orbit 15992, December 24, 2012; 88.89° angle of incidence, long focus resolution roughly 8 to 10 meters per pixel from 89.44 km above 19.97°S, 119.15°E [NASA/GSFC/Arizona State University].

Tsiolkovskiy (184 km in diameter, 20.37°S, 128.97°E), the landmark mare-inundated crater in the lunar highlands south of the farside equator, was conspicuous in our first look at the Moon's farside in 1959.

Also compare this scene - rolling under the sunset terminator (as the Moon was Waxing Full from our standpoint on Earth with the fully-illuminated and closer oblique perspective of the same region from a similar angle six months earlier, HERE.)

This latest LROC Narrow Angle Camera observation is among the 141,630 NAC stills, 23,88 TB of data, released in mid June to the Planetary Data System by the LROC team at Arizona State University, according to Ernest Bowman-Cisneros.

"Additionally," Bowman-Cisneros announced, "the LROC team has been reprocessing data from early in the LRO mission. We have re-released Volume 1, 2 and 3 of the EDR and CDR data sets. Reprocessing will continue until Volumes 4 through 11 have been updated.

"To date, the LROC Team has delivered 1,041,298 LROC images - totaling 123 TB for EDR and 235 TB for CDR products, and over 8,743 derived (RDR) data products to the NASA Planetary Data System," Bowman-Cisneros said. "The complete LROC PDS archive can be accessed via the URL http://lroc.sese.asu.edu/data or one can search for specific images or mosaic products using the LROC WMS Browse interface.

"Also be sure and try out our Quickmap interface."

The full LROC NAC mosaic highly resampled down to the 580 pixel maximum width allowable with this blog format. Captured just before midnight (UT) on Christmas Eve in 2012, most of the interior of of Tsiolkovskiy had already entered the two-week long lunar night, and the high crater rim and central peaks, towering 3200 meters over the crater floor, were mere hours behind. See the mosaic at higher resolutions by right-clicking on the images HERE. [NASA/GSFC/Arizona State University].

The Lunar Reconnaissance Orbiter continues to re-shape the envelope of what was once believed to be possible for long-term lunar missions, having long ago doubled it's record of returning more data to Earth than all other deep space missions combined.It begins a fifth year in lunar orbit, no small achievement itself, having orbited the Moon 18,313 times, as of 3 July, 2013, 2100 UT.

This LROC QuickMap 3D WAC-derived topographical view of Tsiolkovskiy's central peaks has become, more or less, a regular feature, as this distinctive farside crater has been the subject of many interesting posts, some highlighted below [NASA/GSFC/Arizona State University].

Sample Posts regarding Tsiolkovskiy crater:

New oblique view of Tsiolkovskiy central peaks (December 26, 2012)
The Old and the Young at Tsiolkovskiy (October 31, 2012)
Weaving boulder trails on the Moon (July 11, 2012)
Bulging wrinkles at Tsiolkovskiy (January 11, 2010)
Regolith on Basalt (January 10, 2012)
Highland-Mare boundary of Tsiolkovskiy (September 29, 2011)
The Hummocks of Tsiolkovskiy (August 26, 2010)
More of Tsiolkovskiy's boulders and boundaries (August 26, 2010)
Small fractures in the mare floor of Tsiolkovskiy (August 25, 2010)
Tsiolkovskiy - Constellation Region of Interest (May 1, 2010)
Uplift, Boulders of Tsiolkovskiy (September 1, 2009)

Rima Marius Layering

Basalt layering, a slice through the floor of Oceanus Procellarum, is visible along the wall of this section of Rima Marius. LROC Narrow Angle Camera (NAC) Extended Science Mission observation M1103881010R, LRO orbit 14991, October 3, 2012; 21.88° angle of incidence over a 1.3 km-wide field of view, resolution 0.99 meters from 121.1 km  [NASA/GSFC/Arizona State University].

Sarah Braden
LROC News System

Mare basalt layering is visible in the walls of a number of impact craters such as Caroline Herschel Crater and Pytheas Crater. Layers were seen in the wall of Hadley Rille near the Apollo 15 landing site and Today's Featured Image shows a few layers of mare basalt along the top edge of the wall of Rima Marius.

Look closely at the Featured Image to see the individual layers.

Rima Marius is about 280 km long, sinuously slicing through large extents of mare basalt. The are seen in the Featured Image is centered at 14.986°N, 311.565°E.

LROC Wide Angle Camera context view of the southern leg of winding Rima Marius. The arrow marks the location of the field of view shown at high resolution in the LROC Featured Image. LROC WAC M166161047CE (604 nm) spacecraft orbit 9621, July 2, 2011, 63.53° angle of incidence, 58.9 meters resolution from 42.35 km [NASA/GSFC/Arizona State University].

Rilles form when large volumes of low viscosity magma erupt and flow turbulently. The erosive force of the turbulent flow carves a channel into the lunar surface and then drains away, leaving behind an empty groove in the Moon. Studying the thickness of mare basalt layers using areas like the Feature Image help scientists model the viscosity and eruption volume of single eruption events.

The 280 km length of Rima Marius and the LROC Featured Image field of view (arrow) as seen from Earth is more easily seen through telescopes from Earth with the lengthening shadows of local late afternoon illumination, a few days after a Full Moon. In this crop, from a high-resolution lunar mosaic captured by Yuri Goryachko and colleagues at Astronominsk in Belarus, September 25, 2008, shows vast context for Rima Marius within central Oceanus Procellarum, from the Aristarchus Plateau in the North to the Marius Hills, Marius crater and Reiner Gamma swirl albedo to the south [Astronominsk].

Explore the entire LROC NAC for more Rima Marius, HERE.

Related Images:
Dark surface materials surrounding Rima Marius
Discontinuous rilles
Hadley Rille and the Mountains of the Moon
Layers near Apollo 15 landing site

Love U, on the farside of the Moon

A small crater on the inner rim of the farside highlands crater Love U (5.535°S, 128.024°E). LROC NAC M159114365R, LRO orbit 8582, May 4, 2011; 39.5° angle of incidence image, 61 cm resolution from 59.82 km [NASA/GSFC/Arizona State University].

Sarah Braden
LROC News System

The 320 meter diameter crater in today's Featured Image is located inside the larger Love U crater (12 km, 5.535°S, 128.024°E).

Why does this fresh crater look "squished" on one side? The inner wall of Love U slopes downwards from the lower left to the upper right. The lower left hand portion of the crater rim is crisp and unmodified, because it is the upslope part of the crater.

The upper right hand half of the crater rim is not circular and is very modified by debris that fell downslope.

Asymmetric craters are sometimes due to the trajectory of the impacting bolide being less than 15° from the surface (oblique impact). The ~26° slope of Love U's inner wall dominates the morphology of the crater in the Featured Image. The rays of the crater are also asymmetric; longer rays extend downslope into Love U crater.

LROC image-derived Digital Terrain Model (DTM) of Love U crater and surroundings, generated on the fly using the latest generation of their versatile Quick Map application. The crater of interest is seen "on edge" (arrow) from this perspective [NASA/DLR/GSFC/Arizona State University].

For more love on the Moon, remember this lunar valentine HERE?

LROC Wide Angle Camera (WAC) context view (with false-color relative elevation) of Love U; white box outlines the field of view shown in detail in the LROC Featured Image [NASA/GSFC/Arizona State University].

The WAC image above shows that Love U is part of a crater chain. Some of the craters in the chain are oval or elongated, which indicates that they are probably secondaries from a large impact. Crater chains can be formed by secondary craters, volcanic collapse in association with graben, or primary impacts from a string of smaller bolides. Planetary scientists use morphologic and contextual clues to determine how a crater chain formed.

Love U is a satellite crater of the main crater Love, a 90 km diameter, highly degraded crater on the far side of the Moon. The namesake of Love crater is Augustus Edward Hough Love, a mathematician who is well known for Love waves and Love numbers.

Explore the entire NAC image, HERE.

Related Images:
Lopsided La Perouse A
Top of the Landslide
Oval Crater

Earth's Nightlight

Full Moon in natural color, January 2, 2007

Paul D. Spudis
The Once and Future Moon
Smithsonian Air & Space

As a naturally orbiting object, the Moon orbits Earth in an elliptical path, with the center of the Earth at one focus – more precisely, both Earth and Moon orbit each other around what it called the barycenter, the imaginary point about 1800 km below the surface of the Earth that constitutes their mutual center of gravity.  Since the Moon is only about one percent the mass of Earth, the barycenter is much closer to the center of Earth than it is to the center of the Moon.

When the Moon comes closest to Earth in its elliptical orbit it is said to be at perigee.  If the Sun, Earth and Moon come into alignment along a straight-line, a condition occurs that astronomers perversely have named syzygy (a great word to keep in your hip pocket the next time you play Scrabble, though you’ll need a blank to get there).  Syzygy (alignment) is not the same as perigee (the closest approach of Moon to Earth) but on the occasion when syzygy and perigee coincide, we have what’s called a “Super Moon.”

During perigee, the Moon’s elliptical orbit causes it to be about 45,000 km closer to Earth than at farthest point (apogee).  As the average distance between the two is about ten times that distance, the visual effects of this variation, though not large, is measurable.  I’ve been skeptical about noticing this size difference by “eyeballing” the Moon at perigee (closest) and apogee (farthest).  However, during an early morning walk with the dog this last weekend, I was somewhat startled to see the full Moon low in the sky, definitely appearing larger than usual.

In part, this appearance results because of the “Moon illusion,” whereby the Moon appears much larger on or near the horizon than when it is overhead, near zenith.  The traditional explanation for this illusion is that when the Moon is near the horizon, we can compare the size of the Moon’s apparent disk to known objects on the Earth (such as a house, distant tree or hill).  When the Moon is directly overhead, there is no nearby object with which to compare it.  Many depictions in art show the Moon as an enormous lunar disc, glowing the night sky; it is to this optical illusion that such portrayals refer.

The Moon’s apparent diameter is about one-half of a degree of arc (same as the Sun), or roughly the dimensions of a small pea held at arm’s length.  Although the biggest object in our sky, that size is much too small for the naked eye to resolve most surface features (except for the vague markings of light and dark that comprise the lunar maria, the “Man in the Moon”).  In full phase, the Moon can be quite bright, illuminating the landscape at about -12 visual magnitude.  While no one would mistake such conditions with daylight (the Sun is about -26 visual magnitude, about 400,000 times brighter than the full Moon), full moonlight is bright enough to cast strong shadows and to read by.  This is one of the reasons astronomers “hate” the Moon – during full phase, the sky is typically too bright to reveal any but the very brightest stars and it interrupts their views of coinciding meteor showers.   However, they’ll “love” the views that await them from the far side of the Moon, the only place in our Solar System where radio noise from Earth is silent and at times, when Earth blocks the Sun, the sky-viewing would be unsurpassed.

The most important effect of a “Super Moon” is on tides, which can be extraordinarily high during perigee.  This effect can be especially significant in coastal areas that experience high tides, such as the famous Bay of Fundy in Canada.  In this area, the combination of shore depth and geometry, prevailing winds and position create tidal height variations as high as 16 meters (over 52 feet) in the course of a day.  At Super Moon, tidal variations are at their largest; during the passage of Hurricane Sandy up the East Coast last year, landfall occurred during full Moon (syzygy), resulting in both a storm surge (i.e., a large dome of water caused by low atmospheric pressure and wind) and high gravitational tides.  As witnessed with Hurricane Sandy, the combination of both occurring together can be devastating.

Contrary to an illusion of our Earth-bound perspective, the Moon does not orbit Earth's center, rather both Earth and Moon revolve around their common center of gravity, the barycenter of the Earth-Moon system. That moment of inertia, at any given time, is about one-third the distance from Earth's surface and its center GravitySimulator.com

Tidal effects are most notable in large bodies of water, but the solid Earth also deforms in response to the pull of the Moon’s gravity.  On both objects, a tidal bulge extends slightly above the mean radius of both Earth and Moon.  This bulge is not perfectly aligned with the geometric line that connects the centers of the two objects because both Earth and Moon are rotating, and it takes time for the solid bodies to deform plastically.  Thus, the tidal bulge of the rapidly spinning Earth slightly leads the Earth-Moon line, resulting in a constant increased tug at the Earth by the Moon, slightly slowing the rate of Earth’s rotation down.  At the same time, this leading tidal bulge attracts the Moon more, making it speed up in its orbital path slightly and thus, move outward, away from the Earth.  So over time, as the Earth spin rate slows, the Moon gradually recedes away from its grip; this rate of recession is about 4 cm per year.  The Moon is currently about 60 Earth radii away; it was once much closer, possibly as close as a few Earth radii.  It could not be closer than about 3 radii (the Roche limit) because at distances closer than the Roche limit, tidal forces would tear the Moon apart.  In a few hundred million years, the Moon will be too far away to permit a total solar eclipse to be seen from Earth.  A timely and good thing that we came along when we did!

Using information from a lunar seismic network deployed on the Moon during the Apollo missions, we know that “moonquakes” often correlate with the tidal flexing of the solid Moon induced by the Earth (which is much larger than the terrestrial bulge because Earth is much more massive).  In fact, although there is a slight suggestion that the Moon might induce the initiation of an earthquake, in most cases there is no obvious connection.  The Earth is an active, dynamic body and its great internal heat and complexity of configuration appear to be more important in determining when and where an earthquake occurs than by tidal effects caused by the Moon.  But if the proper tidal conditions and the alignment of stress and magnitude of effect coincided, there is no reason that either syzygy or Super Moon could not induce an earthquake.

Our Moon is much more than the familiar, comforting nightlight orbiting Earth.  Beyond touching us emotionally and affecting our planet physically, the Moon is also an orbiting treasure trove of, as yet unrealized (some imagined but mostly yet unimagined) scientific discoveries and technological breakthroughs.  But before we make it our goal to settle the Moon, we must make it our goal to sail beyond it.

Originally published June 26, 2013 at his Smithsonian Air & Space blog The Once and Future Moon, Dr. Spudis is a senior staff scientist at the Lunar and Planetary Institute. The opinions expressed are those of the author but are better informed than average. 

Farside Boulders, Curve Northeastward

Curved boulder tracks outside the rim of a fresh crater on the farside highland terrain southeast of Mare Moscoviense. LROC Narr wo Angle Camera (NAC) observation M143594908L, spacecraft orbit 6295, November 10, 2010; field of view 320 meters across, 39.27° angle of incidence, resolution 58 cm per pixel from 55.36 km [NASA/GSFC/Arizona State University].

Sarah Braden
LROC News System

The boulders in the Featured Image all curve to the northeast, carving dark paths across the fresh rays from a small 525-meter crater on the lunar farside northeast of Van Gent U, 17.233°N, 157.367°E.

The boulders originated from the impact crater itself, being ejected during the impact event with a velocity radial to the crater rim.

As the boulders bounced and rolled along the surface they lost speed (kinetic energy) and slowed, creating gently curving paths until they came to a stop.

Wider field of view from LROC NAC M143594908L, context showing the location of the boulders with respect to their source crater in a field of view 1.9 km across [NASA/GSFC/Arizona State University].

The curved paths are likely caused by the preexisting slope of the topography, which is slightly downward sloping to the northeast (~10°). The linear striations of the fresh ejecta define the radial direction away from the crater and provide a beautiful contrast for the curved boulder paths.

Using the latest LROC QuickMap, a 2.09 by 2.09 km wedge of terrain is shown in 3D, and turned 90° counter-clockwise to show the wider slope where the crater of origin and boulder field are nested in the LROC WAC-derived digital terrain model. The local elevation, from south to north ranges approximately 240 to over 900 meters above global mean [NASA/GSFC/Arizona State University]/

Overall, the fresh material was ejected at higher velocities than the boulders so it is not influenced by the topography and remains on a trajectory radial to the crater.

Explore the entire fresh crater with the LROC NAC, HERE.

Related LROC Featured Images:
Hole in One!
Bounce, Roll, and Stop
Weaving Boulder Trails on the Moon
Rolling Rolling Rolling
Sampling Schrödinger
Central Peak/Mare Boundary

An Oval Crater on Harvey's Wall

A bolide impacting into the sloping south wall of Harvey crater formed an oval rather than circular crater. A 1.32 km-wide field of view cropped from LROC Narrow Angle Camera (NAC) observation M191567120R, LRO orbit 13268, May 13, 2012; 56.78° angle of incidence, resolution 1.36 meters from 136.22 km [NASA/GSFC/Arizona State University].

Lillian Ostrach
LROC News System

Non-circular (oval or elliptical) impact craters can form when the impacting bolide trajectory to the surface is less than 15° from horizontal or when the bolide impacts a sloped region on the (or some combination of both factors). 

This young crater (18.855°N, 213.180°E) formed on the sloping southern wall of Harvey crater, which is very degraded, and may be an example in which target surface slope controlled final crater shape (as opposed to impact angle). The crater is oval-shaped, measuring ~735 m across and ~780 m in the north-south direction.

A closer look, under a higher sun, allows a detailed view of the bright ejecta of the crater of interest. (View the very large, full-sized mosaic HERE.) Full 3 km-width field of view from LROC NAC M138506456L, orbit 5545, September 7, 2010; 29.65° angle of incidence, resolution 66 cm from 63.83 km [NASA/GSFC/Arizona State University].

The southern half of the crater has a well-defined, sharp rim with some concentric fractures (particularly visible on the southwestern rim area) while the northern rim is ill-defined.

LROC Wide Angle Camera (WAC) monochrome mosaic of Harvey crater (19.35°N, 213.49°E, ~60 km diameter). The fresh, oblique impact shown in the LROC Featured Image is on the crater wall, "like flour dropped on the floor," is below left center [NASA/GSFC/Arizona State University].

The poorly-developed northern rim indicates that the impact trajectory probably traveled from the south/southwest toward the north/northeast. In a lower incidence angle image (Sun approaches "noon" position overhead), the albedo variations emphasize the high-reflectance ejecta blanket (observed in the WAC mosaic below) and observations of the ejecta blanket, including the zone of avoidance, help confirm the bolide trajectory.

Harvey, in strategraphic context, itself nested on the northeastern rim of Mach. An arch rim of of an older crater can be seen to the north. The region is further effected by secondary craters from the Mare Orientale impact and elsewhere. LROC WAC-derived digital terrain model [NASA/GSFC/Arizona State University].

LROC NAC images reveal the presence of unexpected ponds of impact melt in small lunar craters. Taking a look at the northern portion of this small crater, there is a smooth deposit with slightly lower reflectance than the surrounding materials. This smooth material is probably a small pond of impact melt, generated during impact. Impact melt is likely distributed elsewhere within the crater as thin veneers, perhaps on the southern wall where there are lower-reflectance smooth streaks, and probably mixed in with the fragmented debris that were not ejected from the crater.

Explore this oval crater for yourself in the full LROC NAC image, HERE.

Related Posts: 
Tres Amicis
Clamshell
A Tiny, Glancing Blow

Complicated Crater

Impact melt, boulders, and mass wasting - oh my! Close-up on the interior of a "complicated," relatively fresh small crater on the floor of Mare Australe. LROC Narrow Angle Camera (NAC) observation M190007628LR, field of view 1 km, resolution 67 cm per pixel from 64.11 km [NASA/GSFC/Arizona State University].

Lillian Ostrach
LROC News System

Relatively fresh, undegraded craters are visually stunning. Today's Featured Image of the interior of a 1.7 km diameter crater (38.728°S, 88.697°E) exhibits just how geologically complicated craters can be! The crater rim is well-formed and relatively distinct, with ejected blocks nearby (some blocks might even fall inside the crater).

Portions of the upper crater walls have jagged, fractured material that may serve as the source for some of the mass-wasting observed lower on the crater walls. There is an approximately 350 meter diameter impact melt deposit on the crater floor. This smooth deposit exhibits polygonal cracks, possibly due to contraction as the melt cooled and hardened. Surrounding the impact melt pond are jumbled piles of blocks, some of which show evidence of impact melt veneer while other boulders landed after the impact melt pond cooled (but "how much later?" is a question we cannot answer easily).

Slightly closer viewing opportunity. LROC NAC mosaic M154649439LR, orbit 7964, 41.98° angle of incidence, 52 cm per pixel resolution, from 49.26 km. View the very large full resolution crop HERE [NASA/GSFC/Arizona State University].

The wide range and contrast of the small crater's fan of ejecta, against the ancient floor of Mare Australe, may be easier to see in this medium resolution crop from the Global Mosaic stitched together from observations swept up by China's Chang'E-2 orbiter. The coloring reflects data collected by the Clementine orbiter in 1994.

LROC WAC monochrome mosaic of the fresh crater north, north of Gum (arrow) [NASA/GSFC/Arizona State University].

Although there are no deep gullies in the upper crater walls, the inter-weaved channels running down the crater walls suggest a complex relationship between impact melt and dry debris flows. The finger-like flow morphology, especially close to the floor melt pond, is similar to impact melt flows elsewhere. However, observations of dry debris flows in other lunar craters are sometimes difficult to distinguish from impact melt. Careful study of stratigraphic relationships is required in cases such as this one to distinguish which material may be melt or dry debris.

Observe the crater wall complexities for yourself in the full LROC NAC image, HERE.

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Farside impact!
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The Moon's antipodal magnetism mystery

A new study of areas on the Moon opposite (at the antipodes) of the Moon's youngest basins goes beyond long-studied crustal magnetic anomalies and the albedo "swirls" at those opposite coordinates to demonstrate "highly modified terrain" at these opposing points. Animation from preliminary lunar crust thickness maps derived from GRAIL (2012) data by the Science Visualization Studio. [NASA/GSFC].

Paul D. Spudis
The Once and Future Moon
Smithsonian Air & Space

Although the Moon has no global magnetic field like the Earth, small areas on its surface are magnetized.  These fields are not systematically distributed and in general are very weak.  In trying to explain their mysterious presence and origin, several ideas have been advanced.

Rocks typically acquire magnetism (called remnant magnetism) by cooling in the presence of a magnetic field.  At temperatures greater than about 570° C (the so-called Curie point), a rock cannot retain a magnetic signature.  But if it cools below the Curie point, it assumes an induced magnetic field oriented in the same direction as the field in which it cooled.  Unfortunately, on the Moon most rocks have been dislodged from their original orientations by impact processes, so we do not know whether a given rock cooled in the presence of a global (presumably uniform strength and direction) or local (randomized) magnetic field.

We knew the Moon had no global magnetic field before the Apollo crews landed, so it was a bit surprising to learn that some of the returned lunar rocks are strongly magnetized.  Because these rocks are all very old (usually much older than 3 billion years), it was thought that they recorded an ancient epoch when the Moon might have had a global magnetic field, now vanished for some reason.

This finding from the lunar samples was complemented by measurements from orbit that show small areas (10s to 100s of kilometers across) of the surface to be magnetized.  These areas occur all over the Moon and are not associated exclusively with either the dark volcanic maria or the bright highlands crust.  However, they do tend to have two peculiar properties.  First, we find strange “grooved” terrain associated with some of the strongest magnetic anomalies.  This terrain is unlike any other lunar landform – it consists of ridges and valleys that cover the walls and sides of craters and mountains.  Second, these magnetic anomalies tend to occur at the antipodes of (180° away on the opposite side of the globe from) the largest and youngest lunar multi-ring impact basins.  These are curious properties indeed.  What might it mean?

For years, many have pondered and worked on this dilemma.  One idea was developed that perhaps these magnetic anomalies are formed during basin impact.  It was proposed that seismic shaking from these enormous impacts created the grooved terrain and induced fractures in the crust at the antipode, into which hot volcanic magma was injected.  After cooling these dikes assumed remnant magnetism from a global dipole field.  Yet another idea contends that the concentration of magnetized material is a result of antipodal convergence of basin ejecta, which arrived hot from basin formation, collected at the antipode and cooled through the Curie point there.  This last model has the advantage that it might also explain the presence of the grooved terrain, which might have formed by the arrival of basin ejecta on the surface from impacts coming from all directions simultaneously.

Though islands of crustal magnetism are strongly associated with points diametrically opposite from basin forming impacts, these magnetic anomalies are also often offset from those antipodal points. Above, the ring of the Moon's youngest basin Schrödinger, in the far lunar south, is mirrored on the area on the direct opposite side of the Moon in the far lunar north. The absolute antipode is in the vicinity of Anaximenes H. The crustal magnetism mapped using Lunar Prospector data seems at its highest near Catena Sylvester. Terrain cited as greatly disrupted seismically is further still from the Schrödinger antipode, at craters Froelich and Lovelace, just beyond this field of view, at upper right [NASA/GSFC/ASU].

My colleague Lon Hood from the University of Arizona has been studying magnetic anomalies for many years and is an advocate of the last model described above.  Hood was studying some previously ignored, smaller magnetic anomalies found around the Moon that had no explanation. He asked me about the geological setting of one particular magnetic anomaly on the Moon that had yet to be described in detail.  This one occurs in highlands near the north pole of the Moon and had not been previously studied in detail.

I have been something of a skeptic for many years about the basin/antipode relation for magnetic anomalies.  Part of the reason for my position is the problem of Reiner Gamma, which is a bright patch on the lunar surface that has one of the highest magnetic field strengths on the Moon.  The problem is that Reiner Gamma is nowhere near the antipode of any basin and shows no evidence for any grooved terrain.  So I thought that this was the exception that disproves the rule.

“Will your grace command me any service to the world's end?  I will go on the slightest errand now, to the Antipodes that you can devise to send me on…”

- Much Ado About Nothing, (Act II, scene 2)

Nonetheless, I was intrigued by Hood’s finding and decided to examine the area.  To my astonishment, I found wall textures very similar to the famous grooved terrain in the walls of the craters Lovelace and Froelich (not exactly coincident with the anomaly, but very close).  I can see no obvious reason for such terrain development; it appears to be highly restricted in its distribution and is not a fresh feature.  Judging from its degraded appearance, it is rather old.

So, is there a basin antipodal to Lovelace and Froelich?  Indeed there is – the fabulous Schrödinger basin, one of the smaller lunar basins at 325 km diameter, located near the south pole of the Moon.  Before our study, I probably would have thought that Schrödinger was too small to create any global-scale effects, but we don’t fully understand the effects of impact with increasing size and there is no good alternative explanation for the wall textures of these two craters.  The presence of a significant magnetic anomaly nearby is unquestionable.

Froelich (l) and Lovelace (r), adjacent to Catena Sylvester (above map) and the region antipodal to Schrödinger basin - showing grooved terrain in walls (green arrows).

From Hood, et al (2013). Along with its spectacular lunar swirls and complex crustal magnetism, grooved terrain along the walls surrounding Mare Ingenii is also a easily identified characteristic of the region adjacent to the antipodes of Mare Imbrium. Less well-known, perhaps, is the region antipodal to Mare Serenitatis, along the north rim of the more ancient South Pole-Aitken basin [NASA/GSFC/ASU].

So have I changed my mind on the origin of lunar magnetic anomalies?  Possibly.  One of the most convincing ways to get a scientist to change his mind is to bludgeon him with an irrefutable fact that contradicts his worldview.  I now realize the Reiner Gamma problem does not “disprove” the basin antipode model – it merely indicates that it may be incomplete.  That distinction is subtle but significant.  In science, we always look for “rules,” generalities that help us organize observations and suggest possible explanations.  However, these rules sometimes have exceptions and we must carefully distinguish which actually have the force of a rule versus those that merely indicate some general tendencies.

To me, this discovery was surprising.  The new finding still does not fully address exactly how these magnetic anomalies are formed at the antipodes, but the concept that magnetic anomalies and basin-forming impacts are intimately associated has been strengthened and extended.  We will continue to work on this vexing problem.

Originally published June 19, 2013 at his Smithsonian Air & Space blog The Once and Future Moon, Dr. Spudis is a senior staff scientist at the Lunar and Planetary Institute. The opinions expressed are those of the author but are better informed than average.

Related Posts:
Bubble, Bubble – Swirl and Trouble (July 19, 2012)
Boulder 668 at Descartes C (July 16, 2012)
LROC: The Swirls of Mare Ingenii (June 22, 2012)
Remnant magnetism hints at once-active lunar core (January 27, 2012)
Grand lunar swirls yielding to LRO Mini-RF (October 4, 2010)
Another look at Reiner Gamma (June 30, 2010)
LOLA: Goddard (June 26, 2010)
Depths of Mare Ingenii (June 16, 2010)
LROC: Ingenii Swirls at Constellation Region of Interest (May 26, 2010)
Local topography and Reiner Gamma (May 22, 2010)
Lunar swirl phenomena from LRO (May 17, 2010)
The still-mysterious Descartes formation (May 11, 2010)
Dust transport and its importance in the origin of lunar swirls (February 21, 2010)
The Heart of Reiner Gamma (November 17, 2009)
Moon’s mini-magnetospheres are old news (November 16, 2009)
MIT claim of solving ‘lunar mystery’ unfounded (January 15, 2009)

"Ka Pow!" on Joliot's central peaks

High-reflectance ejecta and low-reflectance impact melt streamers surround this fresh impact crater on the slopes of the central peak formation of Joliot crater. LROC Narrow Angle Camera (NAC) mosaic M189994606R, LRO orbit 13048, April 25, 2012; field of view 2.25 km, 43.12° angle of incidence at 1.11 meters per pixel resolution, from 147.53 km [NASA/GSFC/Arizona State University].

Lillian Ostrach
LROC News System

High-reflectance ejecta blankets the terrain surrounding a 650 meter diameter crater (26.525°N, 93.518°E).

From samples collected during the Apollo missions we know that high-reflectance ejecta represents recently exposed material that has not yet been affected by space weathering processes (maturity rays) or material exposed that is a different composition than the surrounding area (compositional rays).

The impact crater in the opening image formed near the base of the central peak of Joliot crater (172.79 km in diameter, 25.79°N, 93.39°E), the floor of which was partially flooded with volcanic material. What type of ejecta rays are observed in today's Featured Image - compositional or maturity?

LROC WAC monochrome mosaic of the central interior of Joliot crater, with a fresh impact (arrow) at the base of the central peak complex [NASA/GSFC/Arizona State University].

The crater formed on the base of the central peak which is likely highlands material. The rays extend outward more than two crater diameters onto the mare material. Thus we have an example that is both a maturity ray and compositional ray. Over time as the ejecta matures, the portion on the highlands material will be indistinguishable, while the portion on the mare will still be visible. The much larger crater Tycho (93 km diameter) shows the same combination maturity-compositional rays.

Explore the full LROC NAC image for yourself; HERE. Do you see evidence for impact melt and if so, what do you see (ponds, streamers, flows)?

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Revealed Surface, eastern Mare Insularum

Southern slope of unnamed fracture along the eastern mare/highland boundary of Mare Insularum. LROC Narrow Angle Camera (NAC) frame M1114199297R, LRO orbit 16439, January 30, 2013; 1147.2 meter field of view centered on 13.135°N, 355.638°E, 42.94° angle of incidence, resolution 0.96 meters per pixel from 114.18 km. (Downslope toward upper-right, north at top) [NASA/GSFC/Arizona State University].

Hiroyuki Sato
LROC News System

Today's Featured Image highlights a portion of an unnamed linear fissure located along the eastern edge of Mare Insularum, near the mare/highland boundary.

The width of this fissure varies from about 1.5 to 2 km, its  length is about 90 km, and it extends in the northwest-southeast direction.

The upper-right portion of the opening image, showing a shallow groove extending from up to middle right of the image, corresponds to the bottom of the fissure. Thus most of the image reveals the southern wall of the fissure.

The LROC Featured Image field of view rendered approximately in elevation data from the LROC WAC DTM. Local slopes in the vicinity of the fracture of interest can be difficult to otherwise see. LROC QuickMap [NASA/GSFC/DLR/Arizona State University].

On this slope, there is a high reflectance area with sinuous boundaries. This unit is hard to interpret in terms of what is on top and what is below, stratigraphically. The sunlight is from left side, highlighting what appears as a slightly raised boundary between the two units (arrows). Elsewhere it looks as if the high reflectance material overlies the lower reflectance material. Which unit is younger? Try counting craters between the two, but be careful, if the units have different hardnesses, then the more coherent unit may preserve craters better. 

Unnamed fracture running northwest to southeast on the eastern side of Mare Insularum and surrounding vicinity in LROC WAC monochrome mosaic (100 meters per pixel), centered is 13.12°N, 355.66°E. The LROC NAC footprint (blue box) and location of the field of view in the Featured Image (yellow arrow) are marked [NASA/GSFC/Arizona State University].

Since this whole area is on a slope, slope failure may have revealed an underlying immature surface. Indeed multiple higher reflectance boulders are sitting at the downslope side of this high reflectance unit. But the upper complicated shapes are difficult to explain by this simple story. Or perhaps low reflectance materials could have slumped and covered portions of the high reflectance material? A high resolution NAC DTM would help scientist unravel this complicated morphology.

Explore this enigmatic patterned surface in full NAC frame yourself, HERE.

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