Scientists have long suspected that Mercury had a volcanically active past, ever since the Mariner 10 flyby in 1975 found large smooth plains areas on the planet. These suspicions were confirmed more recently by the MErcury Surface, Space Environment, GEochemistry and Ranging (MESSENGER) mission. MESSENGER compositional data suggest that much of Mercury's crust consists of volcanic rocks.
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| The northern smooth plains of Mercury, as imaged by the imaging system on the MESSENGER mission, with the colour enhanced to show off differences in composition. Image Credit: NASA/ JHU - APL/Carnegie Inst. of Washington |
The problem is that these plains are rather dull as far as volcanic features go, at least when compared to other planets. The Mercury plains are vast flat areas with very few distinctive features. No spectacular volcanic edifices, like we see on other planets. Even vents that represent the source of the lava are not generally found.
That's why scientists were so excited to find some interesting volcanic features in the high northern latitudes of Mercury a few years ago. These features showed quite clearly that large quantities of lava had flowed in torrents across the surface of Mercury in the past.
Dr. Paul Byrne from the Carnegie Institution of Washington, working with colleagues on the MESSENGER science team, identified a number of channels at the edges of the vast smooth plains in the northern parts of Mercury. Some of the channels are broad and straight, while others are narrow and sinuous, winding through the rugged terrain, though all of the channels appear to have served as conduits for hot lava flows. As such, the floors of the channels tend to be smooth and often contain kipukas, which are elevated islands surrounded by lava flows. The kipukas here seem to represent the remnants of ancient impacts, most likely uplifted central peaks of craters, their rims, or even rubbley ejecta, all of which have been flooded by more recent volcanic materials. Some of the kipukas also show signs of having been sculpted by the lava flows that rushed past them; their shapes are streamlined and elongated parallel to the sides of their channels.
Using images from the Mercury Dual Imaging System (MDIS) cameras on board the MESSENGER spacecraft, Dr. Byrne and his colleagues have now studied these channels in greater detail. The channels mostly connect different degraded impact basins together. These basins (which are bigger than 100 km in diameter) seem to have been flooded by lavas, which then breeched the perimeters of the basins and proceeded to further erode and widen existing gaps, often causing entire portions of the weakened basin rim to fail.
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| Flat-floored channels near the northern smooth plains of Mercury, contain streamlined islands that appear to have been sculpted by hot lava as it flowed around them. Image Credit: NASA/ JHU - APL/Carnegie Inst. of Washington |
This kind of information, along with studies of other surface features, was used to determine how fast the lava would have flowed and filled up the downstream basins. For the lava not to cool before it could reach the end basin, it had to have been very hot and very runny. Also, there must have been lots of it. Dr. Byrne and his colleagues estimate that under such conditions, basins of the size seen in this region would have been filled up within a matter of 2 weeks to a month. Furthermore, such large quantities of hot lava would have actually been able to melt these channels into the surface. In other words, these channels have been carved out of the existing rugged terrain by hot, runny lava, much like hot wax can carve out channels in cold older wax!
So, the question then is, why don't we see more of these kinds of features throughout the plains areas of Mercury? The current thinking is that the channels that we do see represent the "last gasp" of volcanism on Mercury. Dr. Byrne's flow studies suggest that the lavas here may have originated from the vast volcanic plains in Mercury's northern areas. It is thought that the northern plains would have originally contained numerous such flow channels, which were then flooded by large quantities of lava that now make up the huge flat plains. Towards the edges of the plains, however, flow channels would have been left behind as the magma supply ran out before the channels could be covered up.
The most interesting thing about these channels is how much they resemble outflow channels on Mars, which are thought to have been formed by catastrophic floods of water. In fact, such channels are often used as evidence for a watery Martian past. However, liquid water is not stable at the temperatures and pressures found on the surface of Mercury, so the features on Mercury can't have been formed by water. They must have been formed by volcanic processes. And, if they can be formed by volcanic processes on Mercury, perhaps they can also be formed this way on Mars. Maybe water is not needed to explain the existence of such land forms anywhere. It's an intriguing thought and means we really need to go back and take a more careful look at these features on Mars.
You can explore channels and other features on Mercury for yourself at the ACT-REACT QuickMap online MESSENGER image tool. To go directly to the study area discussed above, click HERE.
Source: Byrne et al., 2013, An assemblage of lava flow features on Mercury, JGR, DOI: 10.1002/jgre.20052.
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