Tuesday, December 27, 2011

MESSENGER 2011 - A Year in Review


As we prepare to bid farewell to 2011, the MESSENGER spacecraft is now nine months into its orbital mission. The scientific products that MESSENGER has returned have given planetary scientists and space enthusiasts around the world a chance to better understand Mercury's formation, surface composition, and unique atmosphere-magnetosphere system. The Mercury Dual Imaging System (MDIS) has captured >99.9% of Mercury's surface in high resolution, including previously unseen terrain. As the mission moves forward into 2012, we are excited to continue to unravel the mysteries of this planet of extremes. Let's take a look back at some of this year's highlights:

January: Are we there yet?
February: Getting closer... A Solar System Family Portrait, from the Inside Out (second row)
March: Mercury Orbit Insertion! First Image Ever Obtained from Mercury Orbit (top left)
April: X Marks the Spot (top middle)
May: Another Look at Atget (top right)
June: What Happens in Degas Stays in Degas (bottom left)
July: Memories of Many Mixed Materials (third row, middle)
August: A Crater in CloseUp (third row, left)
September: Stunning Landforms in Raditladi Basin (third row, right)
October: The First Solar Day (fourth row, left)
November: Hurrah for the Red and the Blue (fourth row, right)
December: The Bright Rays of Mena (bottom middle), and Mercury Globe: North Pole (bottom right)

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Thursday, December 22, 2011

Inside Eminescu Crater


This oblique view shows a portion of the rim of the crater Eminescu. The angle of this image provides a great perspective for viewing the spectacular cliffs that formed as material slumped from the crater rim into the crater interior, as well as small ponds of impact melt perched on the rim. North is down in this image.

Date acquired: December 05, 2011
Image Mission Elapsed Time (MET): 231611014
Image ID: 1099316
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: 9.8°
Center Longitude: 115.5° E
Resolution: 34 meters/pixel
Scale: The scene is approximately 35 km (22 miles) from north to south.
Incidence Angle: 65.1°
Emission Angle: 60.1°
Phase Angle: 125.3°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Wednesday, December 21, 2011

When the Going Gets Weird, the Weird Turn Pro


This view is a close-up of an area featured in a previous Gallery image. The region is located diametrically opposite the Caloris impact basin, and has been affected by converging seismic waves or ejecta that caused the peculiar "hilly and lineated" texture. Members of the Mariner 10 team informally called this the "weird terrain" when it was first discovered in 1974.

Date acquired: August 02, 2011
Image Mission Elapsed Time (MET): 220756231
Image ID: 581158
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: -29.92°
Center Longitude: 342.0° E
Resolution: 235 meters/pixel
Scale: The scene is about 248 km (155 mi.) across.
Incidence Angle: 85.4°
Emission Angle: 19.3°
Phase Angle: 104.7°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Monday, December 19, 2011

A Small Pond


This image shows a small pond of impact melt that was ejected from a crater just out of view. The melt ponded in this low, forming a smooth surface similar to the melt ponds south of Kuiper crater. North is toward the upper right corner.

Date acquired: November 06, 2011
Image Mission Elapsed Time (MET): 229105038
Image ID: 980525
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: 63.9°
Center Longitude: 256.5° E
Resolution: 16 meters/pixel
Scale: The smooth region is approximately 3 km (1.9 miles) across
Incidence Angle: 69.5°
Emission Angle: 15.6°
Phase Angle: 85.2°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Sunday, December 18, 2011

Rays of Light Material


The ejecta of this fresh 20-km impact crater swept the surface, leaving beautiful bright rays. Crater rays fade with time as smaller impacts mix them into the surrounding soil and particles from the solar wind change the surface's chemistry. Given a little time (perhaps a million years or so), this crater will look like the other similar-sized craters in the frame.

Date acquired: November 17, 2011
Image Mission Elapsed Time (MET): 230018573
Image ID: 1023529
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: -51.0°
Center Longitude: 175.1° E
Resolution: 221 meters/pixel
Scale: The rayed crater is approximately 20 km (12 miles) in diameter
Incidence Angle: 53.1°
Emission Angle: 37.8°
Phase Angle: 78.6°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Saturday, December 17, 2011

Fram Rupes


One hundred years ago, on December 14, 1911, Norwegian explorer Roald Amundsen and his party became the first people to reach the Earth's south pole. The name of the ship that carried Amundsen to Antarctica was the Fram. The image above shows a portion of Fram Rupes on the planet Mercury, a long scarp (cliff) formed by compressive forces generated as the planet's interior cooled and contracted.

Date acquired: November 06, 2011
Image Mission Elapsed Time (MET): 229066087
Image ID: 978519
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: -55.5°
Center Longitude: 267.8° E
Resolution: 152 meters/pixel
Scale: The edges of the image are about 157 km long.
Incidence Angle: 67.2°
Emission Angle: 14.9°
Phase Angle: 81.2°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Friday, December 16, 2011

The Bright Rays of Mena


The young rays of Mena crater contrast brightly against the surrounding surface, though the rays will gradually fade with time. The asymmetric pattern of the rays, with a gap in the south-western direction, may be due to the angle at which the impact that formed the crater occurred, or to the fact that Mena formed on the rim of a larger pre-existing impact crater, as seen in this image.

Date acquired: November 12, 2011
Image Mission Elapsed Time (MET): 229581348, 229581352, 229581356
Image ID: 1003074-1003076
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filters: 9, 7, 6 (1000, 750, 430 nanometers) as red, green, blue
Center Latitude: -0.97°
Center Longitude: 234.0° E
Resolution: 257 meters/pixel
Scale: Mena has a diameter of 15 km (9 miles)
Incidence Angle: 29.7°
Emission Angle: 16.3°
Phase Angle: 46.0°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Monday, November 21, 2011

Kertesz Crater Anaglyph


This is an anaglyph created from two images of the crater Kertesz. By viewing images obtained from slightly different perspectives through red-blue glasses, the brain perceives a "3-D" image. The red lens should be on the left eye. With this anaglyph, better results may be achieved by tilting the head slightly to the left. The floor of Kertesz is covered with spectacular hollows. See more images of hollows here (scroll down to "Presenter #2").

Date acquired: July 31, 2011
Image Mission Elapsed Time (MET): 220634378 and 220591163
Image ID: 575037 and 573112
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: 27.4°
Center Longitude: 146.1° E
Resolution: 17 meters/pixel
Scale: Kertesz crater is about 31 km (19 mi.) in diameter.
Incidence Angle: 76.4° and 75.0°
Emission Angle: 30.3° and 40.9°
Phase Angle: 106.7° and 115.9°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Sunday, November 20, 2011

Spanish Bombs


The small crater at the left side of this image is named for Juan de Mena, a Spanish poet of the 15th century. Mena has extensive bright rays, which can be better appreciated in the global map of Mercury (right on the equator, part way in from the left). Mena formed on the rim of an existing crater, which may help to explain the asymmetric pattern of Mena's rays.

Date acquired: April 19, 2011
Image Mission Elapsed Time (MET): 211718303
Image ID: 151162
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: -0.24°
Center Longitude: 236.3° E
Resolution: 254 meters/pixel
Scale: The image is about 138 km (85 mi.) wide.
Incidence Angle: 65.9°
Emission Angle: 22.3°
Phase Angle: 43.6°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Saturday, November 19, 2011

Complex Craters


While many of the most spectacular craters on Mercury are young and rayed, the vast majority are older and have been modified by both internal and external forces over time. The large 90-km crater in this image has been deformed by a lobate scarp and battered by craters up to 30 km in diameter.

Date acquired: October 27, 2011
Image Mission Elapsed Time (MET): 228200113
Image ID: 937596
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: 5.65°
Center Longitude: 321.9° E
Resolution: 104 meters/pixel
Scale: The large crater in this scene is approximately 90 km (56 miles) in diameter
Incidence Angle: 69.2°
Emission Angle: 66.8°
Phase Angle: 102.0°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Friday, November 18, 2011

Hollowed Crater


The crater at the center of this image is home to more of the "hollows" that dot Mercury's surface, which appear here as high-reflectance features near the crater's central peak and around its floor-wall boundary. This crater, which does not yet have an official name, was also seen in an early image that MESSENGER captured during the spacecraft's first imaging orbit around Mercury.

This image was acquired as a high-resolution targeted observation. Targeted observations are images of a small area on Mercury's surface at resolutions much higher than the 250-meter/pixel (820 feet/pixel) morphology base map or the 1-kilometer/pixel (0.6 miles/pixel) color base map. It is not possible to cover all of Mercury's surface at this high resolution during MESSENGER's one-year mission, but several areas of high scientific interest are generally imaged in this mode each week.

Date acquired: October 21, 2011
Image Mission Elapsed Time (MET): 227644286
Image ID: 911007
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 7 (748 nanometers)
Center Latitude: -1.98°
Center Longitude: 354.1° E
Resolution: 337 meters/pixel
Scale: The crater at center is approximately 90 km (56 miles) across
Incidence Angle: 79.6°
Emission Angle: 56.2°
Phase Angle: 135.9°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Wednesday, October 26, 2011

Strange Hollows Discovered on Mercury


NASA's MESSENGER spacecraft has discovered strange hollows on the surface of Mercury. Images taken from orbit reveal thousands of peculiar depressions at a variety of longitudes and latitudes, ranging in size from 60 feet to over a mile across and 60 to 120 feet deep. No one knows how they got there.

"These hollows were a major surprise," says David Blewett, science team member from the Johns Hopkins University Applied Physics Laboratory. "We've been thinking of Mercury as a relic – a place that's really not changing much anymore, except by impact cratering. But the hollows appear to be younger than the craters in which they are found, and that means Mercury's surface is still evolving in a surprising way."

Mars Reconnaissance Orbiter spotted similar depressions in the carbon dioxide ice at Mars' south pole, giving that surface a "swiss cheese" appearance. But on Mercury they're found in rock and often have bright interiors and halos.

"We've never seen anything quite like this on a rocky surface."

If you could stand in one of these "sleepy" hollows on Mercury's surface, you'd find yourself, like Ichabod Crane, in a quiet, still, haunting place, with a black sky above your head.

"There's essentially no atmosphere on Mercury," explains Blewett. "And with no atmosphere, wind doesn't blow and rain doesn't fall. So the hollows weren't carved by wind or water. Other forces must be at work."

As the planet closest to the Sun, Mercury is exposed to fierce heat and extreme space weather. Blewett believes these factors play a role.

A key clue, he says, is that many of the hollows are associated with central mounds or mountains inside Mercury's impact craters. These so-called “peak rings” are thought to be made of material forced up from the depths by the impact that formed the crater. Excavated material could be unstable when it finds itself suddenly exposed at Mercury's surface.

"Certain minerals, for example those that contain sulfur and other volatiles, would be easily vaporized by the onslaught of heat, solar wind, and micrometeoroids that Mercury experiences on a daily basis," he says. "Perhaps sulfur is vaporizing, leaving just the other minerals, and therefore weakening the rock and making it spongier. Then the rock would crumble and erode more readily, forming these depressions."

MESSENGER has indeed proven Mercury unexpectedly rich in sulfur. That in itself is a surprise that's forcing scientists to rethink how Mercury was formed. The prevailing models suggest that either (1) very early in Solar System history, during the final sweep-up of the large planetesimals that formed the planets, a colossal impact tore off much of Mercury's rocky outer layering; or (2) a hot phase of the early Sun heated up the surface enough to scorch off the outer layers. In either case, the elements with a low boiling point – volatiles like sulfur and potassium – would have been driven off.

But they're still there.

"The old models just don't fit with the new data, so we'll have to look at other hypotheses."

To figure out how the planets and Solar System came to be, scientists must understand Mercury.

"It's the anchor at one end of the Solar System. Learning how Mercury formed will have major implications for the rest of the planets. And MESSENGER is showing that, up to now, we've been completely wrong about this little world in so many ways!"

What other surprises does Mercury hold? The sleepy hollows of the innermost planet may be just the beginning.


Photo credit (top):   NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington; (bottom):  Science/AAAS

Tuesday, October 11, 2011

Mapping Beethoven


At top, the white line highlights the region of Mercury's surface visible to the XRS during a solar flare on 16 June 2011. Near the center is the ~650-km-diameter Beethoven impact basin at 21° S, 236° E. This region has a higher Mg/Si ratio than the northern plains and is closer in composition to terrestrial komatiites, low-silica, high-temperature volcanic rocks that formed only very early in Earth's history.

Below, smooth plains within the same area have been mapped. In green are plains of volcanic origin. These plains display flooding and embayment relationships and color contrasts typical of volcanic plains on Mercury. Yellow denotes plains of uncertain origin. Though they may also be volcanic, they lack definitive evidence for a volcanic origin and may have formed as fluidized impact ejecta, possibly from the Beethoven impact basin, or as impact melt. In blue are plains that formed when rock was melted by impacts. Even geologically complex regions, such as the area seen here, are often dominated by volcanic deposits, and their compositions are consistent with a volcanic origin.

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Monday, October 10, 2011

The Interior of Kuiper


The rayed crater Kuiper (11.3° S, 328.6° E), as seen by MESSENGER's wide-angle camera. The smooth regions on Kuiper's floor and to its south consist of rock that was melted by the impact that created the crater. This impact melt ponded and solidified as smooth plains. Kuiper is 62 km in diameter and is an important stratigraphic marker in Mercury's geologic history.

This image was acquired as part of MDIS's high-resolution surface morphology base map. The surface morphology base map will cover more than 90% of Mercury's surface with an average resolution of 250 meters/pixel (0.16 miles/pixel or 820 feet/pixel). Images acquired for the surface morphology base map typically have off-vertical Sun angles (i.e., high incidence angles) and visible shadows so as to reveal clearly the topographic form of geologic features.

Date acquired: May 04, 2011
Image Mission Elapsed Time (MET): 212983376
Image ID: 210557
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 7 (748 nanometers)
Center Latitude: -12.33°
Center Longitude: 331.2° E
Resolution: 309 meters/pixel
Scale: Kuiper is 62 km (39 miles) in diameter
Incidence Angle: 78.1°
Emission Angle: 28.0°
Phase Angle: 106.1°

Photo credit:

Sunday, October 9, 2011

A Northern Footprint


The X-Ray Spectrometer (XRS) on MESSENGER collects compositional information for relatively large regions on Mercury's surface, and strong signals are only received during times of high solar activity. The blue region outlined in this wide-angle camera image mosaic shows the region visible to the XRS during a solar flare on 16 April 2011. The XRS data indicates that the area is basaltic in composition, the same type of volcanic rock that comprises the lunar maria. This region is part of the vast, high-reflectance northern plains that cover approximately 6% of Mercury's surface. The 1000, 750, and 430 nm bands of the Wide Angle Camera are displayed in red, green, and blue, respectively.

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Saturday, October 8, 2011

Messenger's First Solar Day


After its first Mercury solar day (176 Earth days) in orbit, MESSENGER has nearly completed two of its main global imaging campaigns: a monochrome map at 250 m/pixel and an eight-color, 1-km/pixel color map. Apart from small gaps, which will be filled in during the next solar day, these global maps now provide uniform lighting conditions ideal for assessing the form of Mercury's surface features as well as the color and compositional variations across the planet. The orthographic views seen here, centered at 75° E longitude, are each mosaics of thousands of individual images. At right, images taken through the wide-angle camera filters at 1000, 750, and 430 nm wavelength are displayed in red, green, and blue, respectively.

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Saturday, August 27, 2011

A View Towards the Plains


This view was captured as MDIS pointed to the east, which is oriented as the top of this image. Smooth plains extend into the distance, while the closer ground near the bottom of the image is more heavily cratered and hence rougher in texture. This location is on the edge of volcanic smooth plains that covers a great extent of Mercury's northern region.

Date acquired: August 12, 2011
Image Mission Elapsed Time (MET): 221626724
Image ID: 622112
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 7 (748 nanometers)
Center Latitude: 62.40°
Center Longitude: 321.6° E
Resolution: 242 meters/pixel
Scale: The bottom of this image is 220 kilometers (140 miles) across
Incidence Angle: 82.5°
Emission Angle: 59.4°
Phase Angle: 142.0°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Friday, August 26, 2011

Double Ring Impact Basin


This image shows a double ring impact basin with a smaller, younger crater superimposed on its rim. Larger impacts, such as the one that created this basin, form ring structures instead of central peaks.

Date acquired: June 02, 2011
Image Mission Elapsed Time (MET): 215511113
Image ID: 329264
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: -80.35°
Center Longitude: 212.0° E
Resolution: 255 meters/pixel
Scale: The large impact crater is ~165 km (102 mi) in diameter.
Incidence Angle: 81.6°
Emission Angle: 0.9°
Phase Angle: 82.2°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Thursday, August 25, 2011

Debussy Crater Rays and a Cosmic Ray


The rays apparent in this spectacular limb image of Mercury come from Debussy, the sharp crater near the terminator. This dominant crater on Mercury was also a part of MESSENGER's historic image of Mercury - the first image ever to be taken from a spacecraft in orbit about this planet. Readers may also notice a streak in the blackness of space in the top right corner of the image. This artifact was produced by a cosmic ray hitting the camera's CCD detector while the image was being collected.

Date acquired: July 26, 2011
Image Mission Elapsed Time (MET): 220137668
Image ID: 550504
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 7 (748 nanometers)
Center Latitude: -27.90°
Center Longitude: 29.17° E
Resolution: 2783 meters/pixel
Scale: Mercury's radius is approximately 2440 km (1516 miles)
Incidence Angle: 65.1°
Emission Angle: 48.2°
Phase Angle: 95.3°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Wednesday, August 24, 2011

Ts'ai Wen-Chi Crater and the Long Scarp


A long scarp runs vertically through the center of this image, deforming pre-existing craters along its length. At the bottom of this image, the scarp cuts through the wall and floor of the crater Ts'ai Wen-Chi (124 km diameter), named for the Han Dynasty poet and composer.

Date acquired: August 04, 2011
Image Mission Elapsed Time (MET): 220977824
Image ID: 591397
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 7 (748 nanometers)
Center Latitude: 27.73°
Center Longitude: 337.4° E
Resolution: 432 meters/pixel
Scale: This image is approximately 600 km (370 miles) across
Incidence Angle: 81.9°
Emission Angle: 38.2°
Phase Angle: 120.2°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Monday, August 22, 2011

Uncharted Territory


This image, captured by the Narrow Angle Camera (NAC), shows a crater in a region of Mercury not seen by Mariner 10. This crater was first imaged during MESSENGER's Mercury flybys, but this is the first image to reveal its detailed morphology. The crater's name will be chosen in accordance with a set of rules established by the International Astronomical Union (available here). Craters on Mercury are named after deceased artists, musicians, painters or authors who have made outstanding contributions to their fields and who have been considered a historically significant figure for at least 50 years.

Date acquired: July 20, 2011
Image Mission Elapsed Time (MET): 219646866
Image ID: 527953
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: 6.70°
Center Longitude: 38.52° E
Resolution: 193 meters/pixel
Scale: This crater is about 113 km (70 miles) in diameter
Incidence Angle: 71.4°
Emission Angle: 15.1°
Phase Angle: 56.2°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Sunday, August 21, 2011

Double Trouble


This image, taken by the Narrow Angle Camera (NAC), shows the double rings of an unnamed peak-ring basin. Concentric ring structures like these form during the impact that creates a basin; the number and characteristics of the rings depend on the size of the impact structure and the gravity of the planet.

Date acquired: July 20, 2011
Image Mission Elapsed Time (MET): 219644470
Image ID: 527930
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: -17.66°
Center Longitude: 45.56° E
Resolution: 175 meters/pixel
Scale: The large double ring basin is about 172 km (107 miles) in diameter.
Incidence Angle: 65.6°
Emission Angle: 0.7°
Phase Angle: 66.1°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Saturday, August 20, 2011

Happy Trails


This view, captured by the Wide Angle Camera (WAC), shows a trail of small craters. Such secondary crater chains are formed when the ejecta from a primary impact fall in the surrounding area, forming their own often overlapping small craters. Also visible in this image are smooth plains, formed by volcanism that has filled in a large impact crater.

Date acquired: July 15, 2011
Image Mission Elapsed Time (MET): 219181924
Image ID: 505807
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 7 (748 nanometers)
Center Latitude: 83.21°
Center Longitude: 173.6° E
Resolution: 155 meters/pixel
Scale: The small crater at the bottom of the image has a diameter of 24 km (15 miles).
Incidence Angle: 85.3°
Emission Angle: 0.2°
Phase Angle: 85.3°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Friday, August 19, 2011

Crater Captivation


This image, captured by the Narrow Angle Camera (NAC), shows an unnamed complex crater in Mercury's southern hemisphere. The smooth crater floor is likely due to impact melt that formed during the collision that produced the crater. Also visible are the peak ring and terraced walls, as well as the ejecta blanket and a large field of secondary craters and crater chains.

Date acquired: July 25, 2011
Image Mission Elapsed Time (MET): 220043917
Image ID: 546489
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: -66.40°
Center Longitude: 81.43° E
Resolution: 326 meters/pixel
Scale: The large crater has a diameter of about 155 km (96 miles)
Incidence Angle: 67.0°
Emission Angle: 33.5°
Phase Angle: 100.5°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Thursday, August 18, 2011

Rembrandt Revisited


This limb image shows Rembrandt, the second largest impact basin on Mercury after Caloris. Discovered during the second MESSENGER flyby, Rembrandt is one of the youngest impact basins on Mercury, as indicated by the relatively low density of impact craters on its rim. A large lobate scarp trending from the southwest to the north crosscuts Rembrandt and several of the smaller craters that have impacted the smooth interior plains.

Date acquired: August 07, 2011
Image Mission Elapsed Time (MET): 221198580
Image ID: 601688
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 7 (748 nanometers)
Center Latitude: -32.95°
Center Longitude: 84.90° E
Resolution: 1756 meters/pixel
Scale: The large impact basin is ~715 km (444 mi) in diameter.
Incidence Angle: 46.3°
Emission Angle: 48.7°
Phase Angle: 95.0°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Wednesday, August 17, 2011

Impact Crater on the Edge of Oskison Crater


This image features a crater situated at the edge of the larger Oskison crater located in the plains north of Caloris basin. Due to MESSENGER's highly elliptical orbit, MDIS's Wide Angle Camera is capable of capturing higher resolution images in Mercury's northern hemisphere, such as this 58 meters per pixel view. A detailed look at the crater reveals its terraced walls, smooth floor, and its superposition on Oskison's shadowed rim.

Date acquired: August 01, 2011
Image Mission Elapsed Time (MET): 220677117
Image ID: 577219
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 7 (748 nanometers)
Center Latitude: 60.18°
Center Longitude: 141.9° E
Resolution: 58 meters/pixel
Scale: This crater is approximately 39 km (24 mi) in diameter.
Incidence Angle: 81.2°
Emission Angle: 0.8°
Phase Angle: 80.5°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Monday, August 8, 2011

Firdousi Crater and Region


This image shows a portion of Mercury's surface mainly consisting of smooth plains material. This lighter, smoother area of plains is younger than the darker, rougher surrounding terrain near the edges of this image. Firdousi crater and its halo of small secondary craters is also apparent in this image, in the lower left quadrant.

Date acquired: July 17, 2011
Image Mission Elapsed Time (MET): 219349510, 219349512, 219349518
Image ID: 513659, 513658, 513662
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 9 (1000 nanometers), 7 (750 nanometers), 6 (433 nanometers) as red-green-blue
Center Latitude: 6.77°
Center Longitude: 69.01° E
Resolution: 1330 meters/pixel
Scale: The large crater in the lower left quadrant of this image is about 134 kilometers (80 miles) in diameter
Incidence Angle: 52.4°
Emission Angle: 0.3°
Phase Angle: 52.4°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Sunday, August 7, 2011

Mercury's Smile


This image taken by MDIS's Wide Angle Camera is dominated by an unnamed basin formed from a large impact on the surface of Mercury. Although the impact was energetic enough to create a central peak ring in the basin, the ring has been mostly flooded by impact melt and/or volcanic plains. To the MESSENGER summer interns, the partial ring of mountains resembles a smile.

Date acquired: July 16, 2011
Image Mission Elapsed Time (MET): 219266241
Image ID: 509587
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 7 (748 nanometers)
Center Latitude: 51.79°
Center Longitude: 82.82° E
Resolution: 203 meters/pixel
Scale: The basin is approximately 180 km (112 mi) in diameter
Incidence Angle: 62.3°
Emission Angle: 0.2°
Phase Angle: 62.5°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Saturday, August 6, 2011

Matryoshka Dolls


The largest crater in this image is superimposed by three different craters that each have central peaks. The largest of these superimposed craters is overlapped by one of the others, creating a small crater partially inside another which in turn has another smaller crater partially inside it. Much of Mercury's surface is heavily cratered so overlapping craters can be seen in many places, including the areas around Camoes crater seen here.

Date acquired: July 13, 2011
Image Mission Elapsed Time (MET): 219038585
Image ID: 499240
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: -53.88°
Center Longitude: 83.80° E
Resolution: 361 meters/pixel
Scale: The largest crater in this image is approximately 105 km (65.24 mi) wide
Incidence Angle: 67.1°
Emission Angle: 2.0°
Phase Angle: 68.9°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Friday, August 5, 2011

Mercury's Surface Variety


This area, previously unseen during the Mariner 10 and MESSENGER flybys, was captured by MESSENGER's Narrow Angle Camera (NAC) in orbit. The view presents both contrasting albedo materials as well as contrasting terrain types. The image includes smooth plains along the left edge and a more rugged surface to the right. A 23-km-diameter impact crater sits between exposures of low reflectance material (LRM) to the east and patches of high albedo material to its west.

Date acquired: July 13, 2011
Image Mission Elapsed Time (MET): 219009759
Image ID: 497191
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: 8.93°
Center Longitude: 91.56° E
Resolution: 180 meters/pixel
Scale: The large crater in this image is approximately 23 km (14 mi) in diameter.
Incidence Angle: 42.8°
Emission Angle: 3.0°
Phase Angle: 39.8°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Thursday, August 4, 2011

A Saucerful of Secrets


The crater with the central peaks in the northeast portion of this image is located on the eastern rim of a large impact basin. Extending westward from this crater is a wrinkle ridge that may have formed due to contraction as lava that flooded the basin cooled. Scientists studying craters and large impact basins on Mercury learn more and more of the innermost planet's "secrets" as new imagery and data from MESSENGER become available.

This image was acquired as part of MDIS's high-resolution surface morphology base map. The surface morphology base map will cover more than 90% of Mercury's surface with an average resolution of 250 meters/pixel (0.16 miles/pixel or 820 feet/pixel). Images acquired for the surface morphology base map typically have off-vertical Sun angles (i.e., high incidence angles) and visible shadows so as to reveal clearly the topographic form of geologic features.

Date acquired: July 13, 2011
Image Mission Elapsed Time (MET): 219011692
Image ID: 497387
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 7 (748 nanometers)
Center Latitude: 69.75°
Center Longitude: 110.8° E
Resolution: 248 meters/pixel
Scale: Image diagonal is ~180 km (112 mi)
Incidence Angle: 71.3°
Emission Angle: 0.2°
Phase Angle: 71.4°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Wednesday, August 3, 2011

The Rays of Qi Bashi Crater


This image, taken by MESSENGER's Narrow Angle Camera, captures Qi Bashi, the brightest crater at the right edge of the view. The brilliant ejecta rays of Qi Bashi extend mostly to the north and south, instead of in all directions. When an impact crater is formed, bright, fresh material is ejected out of the crater into the surrounding area; however, the asymmetrical ejecta as seen here necessitates an extremely low impact angle.

This image was acquired as part of MDIS's high-resolution surface morphology base map. The surface morphology base map will cover more than 90% of Mercury's surface with an average resolution of 250 meters/pixel (0.16 miles/pixel or 820 feet/pixel). Images acquired for the surface morphology base map typically have off-vertical Sun angles (i.e., high incidence angles) and visible shadows so as to reveal clearly the topographic form of geologic features.

Date acquired: July 02, 2011
Image Mission Elapsed Time (MET): 218071882
Image ID: 452164
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Center Latitude: -3.15°
Center Longitude: 162.3° E
Resolution: 199 meters/pixel
Scale: This image is approximately 200 km across.
Incidence Angle: 3.2°
Emission Angle: 24.9°
Phase Angle: 28.1°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Tuesday, August 2, 2011

Xiao Zhao Crater


Xiao Zhao, a relatively small fresh crater, stretches its rays across this entire image, illustrating that small impacts are still quite powerful. The bright crater rays, composed of fresh material excavated by the impact, are contrasted by the older, darker surrounding surface. Another small impact crater well known for its extensive rays is Han Kan.

This image was acquired as a high-resolution targeted observation. Targeted observations are images of a small area on Mercury's surface at resolutions much higher than the 250-meter/pixel (820 feet/pixel) morphology base map or the 1-kilometer/pixel (0.6 miles/pixel) color base map. It is not possible to cover all of Mercury's surface at this high resolution during MESSENGER's one-year mission, but several areas of high scientific interest are generally imaged in this mode each week.

Date acquired: July 11, 2011
Image Mission Elapsed Time (MET): 218840609
Image ID: 489105
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 9 (996 nanometers)
Center Latitude: 14.17°
Center Longitude: 122.3° E
Resolution: 456 meters/pixel
Scale: Diameter of Xiao Zhao is 24.2 kilometers (15.0 miles)
Incidence Angle: 22.1°
Emission Angle: 34.3°
Phase Angle: 56.4°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Monday, August 1, 2011

Mercurian Limb and Terminator


The terminator, the division between night and day, is not as obvious in this image as in some others, but it can be seen on the bottom left portion of the planet in this image. This bottom left edge of Mercury appears to fade away, in contrast to the sunlit limb of the bottom right edge. The terrain near the terminator is heavily shadowed, and some of the neighboring surface is in the darkness of Mercury's night.

Date acquired: June 27, 2011
Image Mission Elapsed Time (MET): 217686237, 217686239, 217686245
Image ID: 433696, 433697, 433701
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 9 (996 nanometers), 7 (748 nanometers), 6 (433 nanometers) as red, green, blue
Center Latitude: -21.98°
Center Longitude: 234.5° E
Resolution: 4128 meters/pixel
Scale: The radius of Mercury is approximately 2440 km (1520 miles)

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Sunday, July 31, 2011

Rembrandt Basin


The large Rembrandt basin is evident on the left side of this image, and, in contrast to the relatively darker material surrounding Rembrandt, Amaral crater and its bright rays can be seen on the right. Rembrandt basin is an area of particular scientific interest due to its large size, young age, and extensional and contractional characteristics. In fact, Rembrandt was highlighted in a publication of Science magazine in 2009 and featured on the cover.

This image was acquired as part of MDIS's color base map. The color base map is composed of WAC images taken through eight different narrow-band color filters and will cover more than 90% of Mercury's surface with an average resolution of 1 kilometer/pixel (0.6 miles/pixel). The highest-quality color images are obtained for Mercury's surface when both the spacecraft and the Sun are overhead, so these images typically are taken with viewing conditions of low incidence and emission angles.

Date acquired: July 11, 2011
Image Mission Elapsed Time (MET): 218833662, 218833682, 218833666
Image ID: 489008 , 489013, 489009
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 9 (1000 nanometers), 7 (750 nanometers), 6 (433 nanometers) as red-green-blue
Center Latitude: -34.67°
Center Longitude: 100.4° E
Resolution: 1853 meters/pixel
Scale: Rembrandt basin has a diameter of 716 kilometers (445 miles).
Incidence Angle: 50.5°
Emission Angle: 0.4°
Phase Angle: 50.5°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Saturday, July 30, 2011

Slumping Impact Crater


This image shows impact craters of varying size and morphology. The crater with the visible central peak on the southern edge of the image displays spectacular wall slumps, which form when material on the steep walls of the crater collapses. This crater also has secondary craters and ejecta radiating from its center.

This image was acquired as part of MDIS's color base map. The color base map is composed of WAC images taken through eight different narrow-band color filters and will cover more than 90% of Mercury's surface with an average resolution of 1 kilometer/pixel (0.6 miles/pixel). The highest-quality color images are obtained for Mercury's surface when both the spacecraft and the Sun are overhead, so these images typically are taken with viewing conditions of low incidence and emission angles.

Date acquired: July 20, 2011
Image Mission Elapsed Time (MET): 219691659
Image ID: 529967
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 7 (748 nanometers)
Center Latitude: 82.08°
Center Longitude: 103.1° E
Resolution: 85 meters/pixel
Scale: Image is approximately 88 km (55 mi) across.
Incidence Angle: 82.1°
Emission Angle: 0.2°
Phase Angle: 82.1°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Thursday, July 14, 2011

A Colorful Mood


This image highlights some of the color features present on Mercury's surface, such as Low Reflectance Material (LRM) and crater rays. Visible in the top left quadrant of this image is the named crater Moody, which has a prominent orange color on its floor in this enhanced color image.

This image was acquired as part of MDIS's color base map. The color base map is composed of WAC images taken through eight different narrow-band color filters and will cover more than 90% of Mercury's surface with an average resolution of 1 kilometer/pixel (0.6 miles/pixel). The highest-quality color images are obtained for Mercury's surface when both the spacecraft and the Sun are overhead, so these images typically are taken with viewing conditions of low incidence and emission angles.

Date acquired: July 03, 2011
Image Mission Elapsed Time (MET): 218154838, 218154854, 218154834
Image ID: 456233, 456237, 456232
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)
WAC filter: 9 (1000 nanometers), 7 (750 nanometers), 6 (430 nanometers) as red-green-blue
Center Latitude: -30.86°
Center Longitude: 149.5° E
Resolution: 1712 meters/pixel
Scale: Moody crater is 83 km (~51.5 mi.) in diameter
Incidence Angle: 32.6°
Emission Angle: 0.5°
Phase Angle: 32.8°

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Thursday, January 27, 2011

Mercury in Color


During MESSENGER's second flyby of Mercury, MDIS acquired a strip of high-resolution images obtained with each of the WAC's 11 different color filters. The graphic shown here displays the resulting enhanced-color mosaic and gives considerable detail about the images, how the mosaic was created, and the geologic features that can be seen.

Currently, these images are the highest-resolution color images ever obtained of the Solar System's innermost planet, but not for long! On March 18, 2011, MESSENGER will enter into orbit about Mercury, and the mission's extensive, year-long science observation campaign will begin. That campaign includes capturing color images of Mercury's surface at higher resolution than ever before.

Special thanks to Kathryn Powell, a summer intern student with the MESSENGER project, for contributing to the content of this graphic. Note: since the original creation of this graphic, the crater identified in the upper right with the label "young rayed crater" has been named Dominici. See PIA12871 to learn more about this recently named crater.

Date Acquired: October 6, 2008
Instrument: Wide Angle Camera (WAC) of the Mercury Dual Imaging System (MDIS)

Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington

Note: There is a very nice annotated poster of this image located here.

Wednesday, January 5, 2011

Mercury Landscape


When MESSENGER first flew by Mercury on January 14, 2008, MDIS acquired images of a large portion of Mercury's surface that had never previously been seen by spacecraft. This mosaic of NAC images shows some of the geologic features discovered during that first flyby that have been subsequently named: the curving cliff face of Beagle Rupes, the elongated crater Sveinsdottir, and the craters Izquierdo and Kunisada flooded with lava.

This year, the MESSENGER spacecraft is positioned once again to visit the Solar System's innermost planet. However, this time, the spacecraft won't just pass by. On March 18, 2011, a 15-minute maneuver will place MESSENGER in orbit about Mercury, making it the first spacecraft ever to do so. The MESSENGER mission will then begin an extensive year-long science campaign to unravel Mercury's mysteries. 2011 promises to be an exciting year of further discoveries for the MESSENGER mission.

Date Acquired: January 14, 2008
Instrument: Narrow Angle Camera (NAC) of the Mercury Dual Imaging System (MDIS)
Scale: Izquierdo Crater is 170 kilometers (106 miles) in diameter.


Photo credit: NASA/Johns Hopkins University Applied Physics Laboratory/Carnegie Institution of Washington