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Atmosphere of Mercury

From Wikipedia, the free encyclopedia

Atmosphere of Mercury
Mercury
Mercury's surface, with the atmosphere too thin to be visible.
General information
Chemical speciesColumn density cm−2; Surface density cm−3[1]
Composition
Hydrogen~ 3 × 109; ~ 250
Molecular hydrogen< 3 × 1015; < 1.4 × 107
Helium< 3 × 1011; ~ 6 × 103
Oxygen< 3 × 1011; ~ 4 × 104
Molecular oxygen< 9 × 1014; < 2.5 × 107
Sodium~ 2 × 1011; 1.7–3.8 × 104
Potassium~ 2 × 109; ~ 4000
Calcium~ 1.1 × 108; ~ 3000
Magnesium~ 4 × 1010; ~ 7.5 × 103
Argon~ 1.3 × 109; < 6.6 × 106
Water< 1 × 1012; < 1.5 × 107

Mercury, being the closest to the Sun, with a weak magnetic field and the smallest mass of the recognized terrestrial planets, has a very tenuous and highly variable atmosphere (surface-bound exosphere) containing hydrogen, helium, oxygen, sodium, calcium, potassium and water vapor, with a combined pressure level of about 10−14 bar (1 nPa).[2] The exospheric species originate either from the Solar wind or from the planetary crust. Solar light pushes the atmospheric gases away from the Sun, creating a comet-like tail behind the planet.

The existence of a Mercurian atmosphere was contentious until 1974, although by that time a consensus had formed that Mercury, like the Moon, lacked any substantial atmosphere. This conclusion was confirmed in 1974 when the unmanned Mariner 10 spaceprobe discovered only a tenuous exosphere. Later, in 2008, improved measurements were obtained by the MESSENGER spacecraft, which discovered magnesium in the Mercurian exosphere.

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Transcription

Mercury is the closest planet to the Sun. As you might expect, that makes it pretty hot. But also, it’s pretty cool. There are seven naked-eye solar system objects in the sky: Mercury, Venus, Mars, Jupiter, Saturn, the Sun, and the Moon. Seven. Each of them was associated with a god in ancient times. Mercury was the Roman messenger of the gods, fleet of foot—literally, he had wings on his shoes—and a rapid traveler. To anyone who’s seen Mercury in the sky, this affiliation with the swift god is no surprise. Mercury the planet moves pretty quickly, visibly changing its position relative to the background stars even after a single night. Despite its speed, the planet never gets very far from the Sun. At best, it can reach a separation of about 28°. That’s about three times the apparent size of your fist held at arms length. In 1639 the Italian astronomer Giovanni Zupi used a telescope to observe Mercury, and he discovered it undergoes a complete cycle of phases over time, just like the Moon does. The only way that can happen is if Mercury orbits the Sun, and not the Earth — another checkmark in the column for heliocentrism, which was starting to look better and better all the time. And of course that’s the way things really are. Mercury is the innermost of the planets in the solar system. It orbits the Sun at an average distance of about 58 million kilometers, roughly a third the distance of the Earth from the Sun. That’s why we never see it stray far from the Sun. From our viewpoint, its smaller orbit keeps it huddled closer to our star. That’s why we see it move so rapidly, too; it’s closer to the Sun, so the gravity it feels from the Sun is stronger, and therefore its orbital velocity is faster than Earth’s. It orbits the Sun once every 88 days. And that’s also why we see undergo phases. When it’s between us and the Sun we’re looking at its dark side, and when it’s on the other side of the Sun we’re looking at its fully illuminated half. In between it goes through the same phases as the Moon: crescent, half full, gibbous, and so on. Not that this is such an easy observation to make. Because it never gets far from the Sun, it’s always low to the horizon after sunset or before sunrise. When we observe it we’re looking through all the muck and turbulence in our air, so it’s usually pretty fuzzy. Making matters worse, it’s a dinky planet, only about 4900 kilometers in diameter, about a third the Earth’s width. One upside to all this is that because it’s close to the Sun, it’s illuminated fiercely, and can be pretty bright even near the horizon. If you ever get a chance to see it, you really should. It’s pretty cool. Mercury’s orbit is weird. It has the most elliptical orbit of any planet, ranging from 46 to nearly 70 million kilometers from the Sun. When it’s closest to the Sun it receives more than twice as much light and heat as when it’s furthest! Mercury is too small and difficult to observe to see surface features on it, which for a long time made it impossible to figure out how long its day is. Astronomers assumed that the tides from the Sun had locked Mercury’s spin so that its day was equal to its year, just like our Moon spins once for every time it goes around the Earth. However, in 1965, astronomers used Doppler radar to observe Mercury and directly measure its spin and they got a surprise: Its day was only 59 Earth days long, not 88. But that’s a significant number as well. To be more exact, the actual length of Mercury’s year is 87.97 days, and the actual length of its day is 58.65 Earth days. If you divide those two numbers, you see their ratio is almost exactly 2/3! It turns out there’s more than one way to tidally lock the rotation of a planet to its orbit. Remember earlier, when I said Mercury’s orbit is highly elliptical? The tides from the Sun are far stronger on Mercury when it’s at perihelion, the closest point in its orbit to the Sun, than when it’s at aphelion, the farthest point in its orbit. After Mercury first formed, tides from the Sun slowed its rotation just like the Earth’s tides on the Moon slowed the Moon down as well. But at some point, Mercury’s spin slowed to where it was 2/3 of its orbital period. So, at one perihelion pass, one side of Mercury faces the Sun. Then, 88 or so days later, it approaches perihelion again. But it’s spun 1.5 times, and this means the exact opposite side of Mercury faces the Sun at this closest approach. 88 days later, Mercury has spun 1.5 times again, and the whole thing repeats. It turns out that’s a perfectly legitimate stable configuration, just like the one-to-one spin/orbit setup. The way the physics works out, tides like simple multiples. Once the day became 2/3 the period of the year, forced by Mercury’s elliptical orbit, the tides stopped slowing it, and things have been that way ever since. Mercury’s elliptical orbit, together with the 2:3 spin to orbit ratio, make for a very, very weird day on Mercury. If you stay in one spot, it takes the Sun two Mercury years, 176 days, for the Sun to go around the sky once! That’s because if you’re on the side of Mercury facing the Sun at one perihelion, the other side will face it one year later. It’ll only be after the second year ends that you’re facing the Sun again. But it gets weirder. Mercury’s spin is constant; it doesn’t speed up or slow down. However, its motion around the Sun is faster at perihelion than aphelion. At aphelion, Mercury’s spin is a bit faster than its orbital speed, so the Sun moves rapidly westward across the sky. But at perihelion Mercury’s motion around the Sun actually more than compensates for its spin, so the Sun appears to stop in the sky and actually move backwards for a few days! Then, as Mercury pulls away from the Sun, its orbital velocity slows down, and the Sun starts to move west once again as the planet’s rotation dominates. If you’re at just the right spot on the planet’s surface, this means you could actually watch the Sun rise, slow, stop, set again, then rise again! And you think time zones on the Earth are a pain. Mercury’s hard to observe from Earth, and much of what we know about it is due to observations from space probes sent there. Mariner 10 made three flybys of Mercury in the 1970s, and mapped about half the surface. We learned that it had almost no atmosphere, and was therefore unsurprisingly covered in craters. In 2011, the MESSENGER probe entered orbit around Mercury after making a series of close flybys. The pictures it returned were breathtaking, and revealed a world that has seen a lot of pummeling over the eons. It’s covered in craters, pole to pole, some hundreds of kilometers in diameter. The largest is called Caloris Basin, a whopping huge impact feature 1600 kilometers across. There are some smoother plains on the planet’s surface too, which appear to be older than the cratered regions. These plains are covered in cracks called rupes. These are compression folds, like wrinkles on a fruit rind that’s dried out. Apparently, as Mercury’s interior cooled after it formed, the planet shrank, and the crust cracked as it tried to shrink as well. Several of the craters have extensive ray systems. Like on our Moon, these are formed when impacts fling out long plumes of material that then settle down on the surface. One of my favorite things of all about Mercury: Craters are named after artists. Musicians, writers, painters, and more, so we have craters like Botticelli, Chekov, Debussy, Degas, Okyo, Sibelius, Vivaldi, and Zola. There’s even one named Tolkien! Dipping below the surface, we can only infer what Mercury’s internal structure is like. But the planet’s dense, nearly as dense as Earth. We know the surface is rocky, so to be as dense as it is it must have a large iron core, far larger in proportion to the planet than Earth’s. Mercury’s core may reach ¾ of the way to the planet’s surface! Why does it have such a high proportion of iron? Mercury may have formed as a larger planet, then got blasted in a huge grazing impact that blew away the lighter materials that had risen to the surface, leaving behind the denser part. Or maybe the heat of the still-forming Sun vaporized the lighter materials off its surface. Mercury has a measurable magnetic field, which is a bit surprising since it rotates so slowly—rotation plays a big part in the Sun’s and Earth’s magnetic fields. But that fits with so much of its interior being molten iron; the bigger core may allow for a stronger field despite its slow spin. It doesn’t have much of an atmosphere, but there is a trace of one, mostly due to its magnetic field trapping the solar wind, and to material flung up from the surface after violent impacts from comets and asteroids. A lot of this material blown off the surface escapes the planet and gets blown away by the solar wind and pressure from sunlight. It forms a long comet-like tail that is tens of millions of kilometers long. This tail is comprised of elements like sodium, calcium, and magnesium, material that’s known to be abundant on the surface. Speaking of which, here’s a fun fact: pound for pound, impacts on Mercury are more violent than they are on Earth. Mercury has weaker gravity, so it doesn’t pull in impactors as hard as the Earth does, but it orbits the Sun far faster than Earth does, so asteroids and comets tend to hit at higher velocity. That makes the explosive energy higher, making craters bigger. And there’s one more surprise Mercury has, and it’s really surprising: Despite being so close to the Sun, and having a surface temperature that can reach 430°C — 800° Fahrenheit — astronomers have found water ice on Mercury! It exists in the bottoms of deep craters near Mercury’s poles, where sunlight never reaches. These are called “cold traps,” and temperatures there don’t get above -170° C. It’s not known for sure where the water comes from, but it’s likely to be from comets and asteroids that impacted the planet, scattering the water across the surface. Of course, in the harsh heat that water just goes Fffffft and goes away. But in those deep craters it can persist, accumulating over the eons. There may be billions of tons of it there! It’s bizarre to think that in one of the hottest places in the solar system there can be conditions so cold ice can exist, but one thing we’ve learned about nature over and again: It has a lot more imagination than we do. Today you learned that Mercury is the closest planet to the Sun. It’s airless and dense, and is covered with craters. Its rotation is locked to its orbit in a 2 to 3 ratio, and together with its elliptical orbit makes a day on Mercury very long and very weird. And despite being very hot, there’s actually water ice in deep craters at its poles. Crash Course Astronomy is produced in association with PBS Digital Studios. Head to their channel to discover more awesome videos. This episode was written by me, Phil Plait. The script was edited by Blake de Pastino, and our consultant is Dr. Michelle Thaller. It was directed by Nicholas Jenkins, edited by Nicole Sweeney, and the graphics team is Thought Café.

Composition

The Mercurian exosphere consists of a variety of species originating either from the Solar wind or from the planetary crust.[3] The first constituents discovered were atomic hydrogen (H), helium (He) and atomic oxygen (O), which were observed by the ultraviolet radiation photometer of the Mariner 10 spaceprobe in 1974. The near-surface concentrations of these elements were estimated to vary from 230 cm−3 for hydrogen to 44,000 cm−3 for oxygen, with an intermediate concentration of helium.[3] In 2008 the MESSENGER probe confirmed the presence of atomic hydrogen, although its concentration appeared higher than the 1974 estimate.[4] Mercury's exospheric hydrogen and helium are believed to come from the Solar wind, while the oxygen is likely to be of crustal origin.[3]

Ca and Mg in the tail

The fourth species detected in Mercury's exosphere was sodium (Na). It was discovered in 1985 by Drew Potter and Tom Morgan, who observed its Fraunhofer emission lines at 589 and 589.6 nm.[5] The average column density of this element is about 1 × 1011 cm−2. Sodium is observed to concentrate near the poles, forming bright spots.[6] Its abundance is also enhanced near the dawn terminator as compared to the dusk terminator.[7] Some research has claimed a correlation of the sodium abundance with certain surface features such as Caloris or radio bright spots;[5] however these results remain controversial. A year after the sodium discovery, Potter and Morgan reported that potassium (K) is also present in the exosphere of Mercury, though with a column density two orders of magnitude lower than that of sodium. The properties and spatial distribution of these two elements are otherwise very similar.[8] In 1998 another element, calcium (Ca), was detected with column density three orders of magnitude below that of sodium.[9] Observations by the MESSENGER probe in 2009 showed that calcium is concentrated mainly near the equator—opposite to what is observed for sodium and potassium.[10] Further observations by Messenger reported in 2014 note the atmosphere is supplemented by materials vaporized off the surface by meteors both sporadic and in a meteor shower associated with Comet Encke.[11]

In 2008 the MESSENGER probe's Fast Imaging Plasma Spectrometer (FIPS) discovered several molecular and different ions in the vicinity of Mercury, including H2O+ (ionized water vapor) and H2S+ (ionized hydrogen sulfide).[12] Their abundances relative to sodium are about 0.2 and 0.7, respectively. Other ions such as H3O+ (hydronium), OH (hydroxyl), O2+ and Si+ are present as well.[13] During its 2009 flyby, the Ultraviolet and Visible Spectrometer (UVVS) channel of the Mercury Atmospheric and Surface Composition Spectrometer (MASCS) on board the MESSENGER spacecraft first revealed the presence of magnesium in the Mercurian exosphere. The near-surface abundance of this newly detected constituent is roughly comparable to that of sodium.[10]

Properties

Mariner 10's ultraviolet observations have established an upper bound on the exospheric surface density at about 105 particles per cubic centimeter. This corresponds to a surface pressure of less than 10−14 bar (1 nPa).[14]

The temperature of Mercury's exosphere depends on species as well as geographical location. For exospheric atomic hydrogen, the temperature appears to be about 420 K, a value obtained by both Mariner 10 and MESSENGER.[4] The temperature for sodium is much higher, reaching 750–1,500 K on the equator and 1,500–3,500 K at the poles.[15] Some observations show that Mercury is surrounded by a hot corona of calcium atoms with temperature between 12,000 and 20,000 K.[9] In the early 2000s, a simulation of Mercury's Na exosphere and its temporal variation was conducted to identify the source process that supplied crustal species to the exosphere. Processes like; evaporation, diffusion from the interior, sputtering by photons and energetic ions, chemical sputtering by photons, and meteoritic vaporization were tested. However, evaporation provides the strongest match when comparing the changes in the sodium exosphere with solar distance and time of day to the 2001 observations of Mercury's sodium tail.[16]

Tails

Sodium tail, photographed by an amateur in Italy
Sodium tail
Sodium tail

Because of Mercury's proximity to the Sun, the pressure of solar light is much stronger than near Earth. Solar radiation pushes neutral atoms away from Mercury, creating a comet-like tail behind it.[17] The main component in the tail is sodium, which has been detected beyond 24 million km (1000 RM) from the planet.[18] This sodium tail expands rapidly to a diameter of about 20,000 km at a distance of 17,500 km.[19] In 2009, MESSENGER also detected calcium and magnesium in the tail, although these elements were only observed at distances less than 8 RM.[17]

Observation difficulties

Mercury is the least explored planet of the inner Solar System due to the many difficulties of observation. The position of Mercury as seen from Earth is always very close to the Sun, which causes challenges when trying to observe it. The Hubble Space Telescope and other Earth-based space imaging systems have highly sensitive sensors so they can observe deep space objects. They must not be directed toward the Sun, lest its powerful radiation destroy the sensors.[16]

Instead, flyby and orbital missions to Mercury can study the planet and receive accurate data. Even though Mercury is closer to Earth than Pluto is, the transfer orbit from Earth to Mercury requires more energy. Mercury being so close to the Sun, space probes going there are accelerating as they approach, due to the Sun's gravitational pull. This requires the use of retrorockets, which use fuel that the probe must carry instead of better instruments.[20]

See also

References

Notes

  1. ^ Killen 2007, p. 456, Table 5
  2. ^ "NASA—Mercury". Archived from the original on 2005-01-05. Retrieved 2009-09-26.
  3. ^ a b c Killen, 2007, pp. 433–434
  4. ^ a b McClintock 2008, p. 93
  5. ^ a b Killen, 2007, pp. 434–436
  6. ^ Killen, 2007, pp. 438–442
  7. ^ Killen, 2007, pp. 442–444
  8. ^ Killen, 2007, pp. 449–452
  9. ^ a b Killen, 2007, pp. 452–453
  10. ^ a b McClintock 2009, p. 612–613
  11. ^ Rosemary M. Killen; Joseph M. Hahn (December 10, 2014). "Impact Vaporization as a Possible Source of Mercury's Calcium Exosphere". Icarus. 250: 230–237. Bibcode:2015Icar..250..230K. doi:10.1016/j.icarus.2014.11.035.
  12. ^ "MESSENGER Scientists 'Astonished' to Find Water in Mercury's Thin Atmosphere". The Planetary Society. 2008-07-03. Archived from the original on 6 April 2010. Retrieved 2010-03-28.
  13. ^ Zurbuchen 2008, p. 91, Table 1
  14. ^ Domingue, 2007, pp. 162–163
  15. ^ Killen, 2007, pp. 436–438
  16. ^ a b Solomon, Sean C (2003). "Mercury: the enigmatic innermost planet". Earth and Planetary Science Letters. 216 (4): 441–455. Bibcode:2003E&PSL.216..441S. doi:10.1016/S0012-821X(03)00546-6.
  17. ^ a b McClintock 2009, p. 610–611
  18. ^ Schmidt 2010, p. 9–16
  19. ^ Killen, 2007, p. 448
  20. ^ Benkhoff, Johannes (2010). "BepiColombo—Comprehensive exploration of Mercury: Mission overview and science goals". Planetary and Space Science. 58 (1–2): 2–20. Bibcode:2010P&SS...58....2B. doi:10.1016/j.pss.2009.09.020.

Bibliography

This page was last edited on 13 May 2024, at 04:16
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