Atmosphere of Pluto

Departure shot of Pluto by New Horizons, showing Pluto's atmosphere backlit by the Sun. The blue color is close to what a human eye would have seen, and is caused by layers of haze in the atmosphere.

The atmosphere of Pluto is the tenuous layer of gases surrounding Pluto. It consists mainly of nitrogen (N2), with minor amounts of methane (CH4) and carbon monoxide (CO), all of which are vaporized from their ices on Pluto's surface.[1][2] It contains layered haze, probably consisting of heavier compounds which form from these gases due to high-energy radiation.[3] The atmosphere of Pluto is notable for its strong and not completely clear seasonal changes caused by peculiarities of the orbital and axial rotation of Pluto.[1]

Surface pressure of the atmosphere of Pluto, measured by New Horizons in 2015, is about 1 Pa (10 μbar), roughly 100,000 times less than Earth's atmospheric pressure. Temperature on the surface is 40–60 K (−233.2 – −213.2 °C),[1] but it quickly grows with altitude due to methane-generated greenhouse effect. Near the altitude 30 km it reaches 110 K (−163 °C), and then slowly decreases.[4]

Pluto is the only trans-Neptunian object with known atmosphere.[4] Its closest analog is the atmosphere of Triton, although in some aspects it resembles even the atmosphere of Mars.[5][6]

The atmosphere of Pluto has been studied since 1980s by way of earth-based observation of occultations of stars by Pluto[7][8] and spectroscopy.[9] In 2015, it was studied from a close distance by the spacecraft New Horizons.[2][10] In September 2016, astronomers announced that the reddish-brown cap of the north pole of Charon, the largest of five moons that orbit Pluto, is composed of tholins, organic macromolecules that may be essential ingredients of life, and produced from methane, nitrogen and related gases released from the atmosphere of Pluto and transferred over about 19,000 km (12,000 mi) distance to the orbiting moon.[11]

Composition

Blue haze bands in Pluto's atmosphere
(approximately true-color)

The main component of the atmosphere of Pluto is nitrogen. Content of methane, according to measurements by New Horizons, is 0.25%.[2][Note 1] For carbon monoxide, the Earth-based estimates are 0.025–0.15% (2010)[13] and 0.05–0.075% (2015).[14] Under influence of high-energy cosmic radiation, these gases react to form more complex compounds (not volatile at Pluto's surface temperatures[15]), including ethane (C2H6), ethylene (C2H4), acetylene (C2H2), heavier hydrocarbons and nitriles[3][16][17] and hydrogen cyanide (HCN)[18] (amount of ethylene is about 0.0001%, and amount of acetylene is about 0.0003%).[2] These compounds slowly precipitate on the surface. Probably, they also include tholins, which are responsible for the brown color of Pluto (like some other bodies in the outer solar system).[2][19]

The most volatile compound of the atmosphere of Pluto is nitrogen, the second is carbon monoxide and the third is methane. The indicator of volatility is saturated vapor pressure (sublimation pressure). At temperature 40 K (close to minimum value for surface of Pluto[1]) it is about 10 Pa for nitrogen, 1 Pa for carbon monoxide and 0.001 Pa for methane. It quickly increases with temperature, and at 60 K (close to the maximum value[1]) approaches to 10 000 Pa, 3000 Pa and 10 Pa respectively. For heavier-than-methane hydrocarbons, water, ammonia, carbon dioxide and hydrogen cyanide, this pressure remains negligibly low (about 10–5 Pa or still lower), which indicates absence of volatility at Pluto's conditions (at least in cold lower atmosphere).[15][20]

Methane and carbon monoxide, due to their lower abundance and volatility, could be expected to demonstrate stronger deviations from pressure equilibrium with surface ices and bigger temporal and spatial variations of concentration. But actually concentration of, at least, methane, does not depends noticeably of height (at least, in the lower 20–30 km), longitude and time.[5][21] But temperature dependence of volatility of methane and nitrogen suggest that concentration of methane will decrease during moving of Pluto further from the Sun.[15][21][22] It's notable that observed concentration of methane is 2 orders of magnitude higher than expected from Raoult's law on the basis of its concentration in surface ice and ratio of sublimation pressures of methane and nitrogen.[5][23] Reasons of this discrepancy are unknown. It can be due to existence of separate patches of relatively clean methane ice, or due to increased content of methane in the uppermost layer of usual mixed ice.[5][22]

Seasonal and orbital changes of insolation results in migration of surface ices: they sublimate in some places and condensate in another. According to some estimates, it gives meter-sized changes of their thickness.[8] This (but also changes in viewing geometry) results in appreciable changes of brightness and color of Pluto.[5]

Methane and carbon monoxide, despite their low abundance, are significant for thermal structure of the atmosphere: methane is a strong heating agent[12] and carbon monoxide is a cooling one (although amount of this cooling is not completely clear).[4][13]

Haze

Haze with multiple layers in the atmosphere of Pluto. Part of the plain Sputnik Planitia with nearby mountains is seen below. Photo by New Horizons, taken 15 min after the closest approach to Pluto.
Curve of absorption of solar ultraviolet by the atmosphere of Pluto, measured during flight of New Horizons across Pluto's shadow. A distinctive kink, created, probably, by the haze,[2] is present both on the decreasing and increasing branches.

New Horizons discovered in the atmosphere of Pluto a multi-layered haze, which covers the entirety of the dwarf planet and reaches altitude over 200 km. The best images show about 20 layers of the haze. Horizontal extent of the layers is no less than 1000 km; vertical distance between them is about 10 km.[10]

Despite the very low density of the atmosphere, the haze is rather appreciable: it even scatters enough light to allow photographing some details of Pluto's night side.[24] Its normal optical depth is estimated as 0.004[2] or 0.013[10] (thus, it diminishes the intensity of a vertical beam of light by 1–e–0.004=0.4% or 1–e–0.013=1.3%; for grazing light the effect is much stronger). Scale height of the haze is 45–55 km;[2][10] it approximately coincides with scale height of pressure in the middle atmosphere.[7] On the heights of 100–200 km it diminishes to 30 km.[10]

Size of the haze particles is unclear. Its blue colour points to a particle radius near 10 nm, but the ratio of brightnesses at different phase angles indicates a radius exceeding 100 nm. This can be explained by aggregation of small (tens of nm) particles into larger (hundreds of nm) clusters.[10]

Probably, the haze consists of particles of non-volatile compounds, which are synthesized from atmospheric gases under influence of cosmic high-energy radiation.[2][3][25] The layers can be formed due to gravity waves (presence of which is also suggested by observations of occultations),[2] and such waves can be created by wind blowing over Pluto's rough surface.[10]

The haze is the most probable reason of a kink on the curve of light intensity vs. time obtained by New Horizons during the flight across Pluto's shadow (on the image) – below altitude 150 km the atmosphere attenuates light much stronger than above. A similar kink was observed during stellar occultation in 1988. Firstly it was also interpreted as weakening of light by haze.[26] Another possible culprit is temperature inversion, and some researchers favoured this explanation.[5] Height of the layer which created the kink relative to surface was impossible to determine at these times due to uncertainty of Pluto's radius. Still, it was possible to calculate its distance from Pluto's center. Subtracting the modern figure for the radius of Pluto, the result is a height of 2±24 km, hence this "haze" is indistinguishable from the surface of Pluto. During later occultations (when the atmosphere of Pluto was already ≥2 times denser) this kink was absent.[4][7][27]

Another evidence of the haze was obtained in 2002 due to a new occultation. The stellar light which managed to reached Earth during the occultation (due to refraction in Pluto's atmosphere), demonstrated an increase of intensity with wavelength.[Note 2][28] This was interpreted as a reliable[5][29] evidence of light scattering by aerosols (similar to the reddening of rising Sun). However, this feature was absent during later eclipses (including 29 June 2015),[5][29] and on 14 July 2015, New Horizons found the haze to be blue.[30]

Possible clouds in Pluto's atmosphere

In the final batch of images received from New Horizons, a number of potential clouds were observed.[31]

Temperature and thermal structure

Pluto has no or almost no troposphere; observations by New Horizons suggest a thin tropospheric boundary layer consistent with those models[21] which predicted its thickness ≤1 km.[2] Above it lays a layer with fast increase of temperature with height: stratosphere. The temperature gradient is estimated to be 2.2,[7] 3–15[12] or 5.5[5] degrees per km. It is a result of greenhouse effect, caused by methane. Mean temperature of the surface is 42±4 K (measured in 2005),[32] and the mean value for all the atmosphere is 90+25
18
K
(2008).[12][13][33]

On the height 20–40 km temperature reaches its maximum (100–110 K; stratopause) and then slowly decreases (about 0.2 K/km;[4] mesosphere).[4][5][7] Causes of this decrease are unclear; it can be related to cooling action of carbon monoxide,[13] hydrogen cyanide or other reasons.[4] Above 200 km temperature reaches approximately 80 K and then remains constant.[4]

Temperature of upper layers of the atmosphere does not show noticeable temporal changes. In 1988, 2002 and 2006 it was approximately constant and equal to 100 K (with uncertainty about 10 K), despite twofold increase of the pressure. Dependence on latitude or morning/evening conditions is also absent: temperature is the same above all the surface.[5] It is consistent with theoretical data, which predict fast mixing of the atmosphere.[5] But there are evidence for a small vertical heterogeneities of temperature. They reveal themselves in sharp and brief spikes of brightness during stellar occultations.[27] Amplitude of these heterogeneities is estimated to be 0.5–0.8 K on the scale of a few km. They can be caused by gravity waves or turbulence, which can be related to convection or wind.[27]

Interaction with the atmosphere significantly influences temperature of the surface. Calculations show that the atmosphere, despite very low pressure, can significantly diminish diurnal variations of this temperature.[34] But there still remain temperature variations about 20 K – partly because of cooling of the surface due to sublimation of ices.[1]

Pressure

Pressure of the atmosphere of Pluto is very low and strongly time-dependent. Observations of stellar occultations by Pluto show that it increased about 3 times between 1988 and 2015, despite that Pluto is moving away from the Sun since 1989.[35][8][34][36] This is probably caused by Pluto's north pole coming into sunlight in 1987, which intensified evaporation of nitrogen from the northern hemisphere,[27][37][Note 3] whereas its southern pole is still too warm for condensation of nitrogen.[8] Absolute values of surface pressure are difficult to obtain from occultation data, because these data do not usually reach the lowest layers of the atmosphere. So, surface pressure has to be extrapolated, and this is somewhat ambiguous due to not completely clear height dependence of temperature and, consequently, pressure. The radius of Pluto must also be known, but it was poorly constrained before 2015. So, precise values of Pluto's surface pressure were impossible to calculate in previous times. For some occultations since 1988, pressure was calculated for a reference level of 1275 km from the center of Pluto (which later turned out to be 88±4 km from the surface).[4][8][34]

Curves of pressure vs. distance from the center, obtained for occultations of 1988 and 2002,[27] in combination with the now known radius of Pluto (1187±4 km[2]) give values of about 0.4 Pa for 1988 and 1.0 Pa for 2002. Spectral data provided values 0.94 Pa in 2008 and 1.23 Pa in 2012 for the distance from the center 1188 km (1±4 km from the surface).[5] An occultation on 4 May 2013 gave data almost precisely for the surface level (1190 km from the center, or 3±4 km from the surface): 1.13±0.007 Pa.[5] An occultation on 29/30 June 2015, just 2 weeks before New Horizons encounter, provided a surface pressure of 1.3±0.1 Pa.[35]

The first direct and reliable data about the lowermost layers of the atmosphere of Pluto were obtained by New Horizons on 14 July 2015 due to radio-occultation measurements. The surface pressure was estimated to be 1 Pa (1,1±0,1 at entry of the spacecraft behind Pluto and 1,0±0,1 at the exit).[10] This is consistent with occultation data from previous years,[10] although some of the previous calculations based on this data gave about 2 times higher results.[2][38][3]

The scale height of pressure in Pluto's atmosphere varies significantly with height (in other words, the height dependence of the pressure deviates from exponential). This is caused by strong height variations of temperature. For the lowermost layer of the atmosphere the scale height is about 17[21]–19[6] km, and for heights 30–100 km 50–70 km.[10][7][26]

Seasonal changes

Due to orbital eccentricity, in the aphelion Pluto receives 2.8 times less heat than in perihelion.[Note 4] It should cause strong changes in its atmosphere, although details of these processes are not clear. Firstly it was thought that in aphelion the atmosphere must largely freeze out and fall on the surface (this is suggested by strong temperature dependence of sublimation pressure of its compounds), but more elaborated models predict that Pluto has significant atmosphere during all its year.[1][8]

Pluto's last passage through its perihelion was on 5 September 1989.[1] As of 2015, it is moving away from the Sun and its overall surface illumination is decreasing. However, the situation is complicated by its big axial tilt (122.5°[39]), which results in long polar days and nights on large parts of its surface. Shortly before the perihelion, on 16 December 1987, Pluto underwent equinox, and its north pole[Note 5] came out of the polar night, which had lasted 124 Earth years.

Data, existing as of 2014, allowed the scientists to build a model of seasonal changes in Pluto's atmosphere. During the previous aphelion (1865) significant quantity of volatile ices was present in both northern and southern hemispheres. Approximately at the same time, the equinox occurred and the southern hemisphere became tilted towards the Sun. Local ices began to migrate to the northern hemisphere, and around 1900 the southern one became largely devoid of them. After the following equinox (1987), the southern hemisphere turned away from the Sun. Nonetheless, its surface was already substantially heated, and its big thermal inertia (provided by non-volatile water ice) greatly slowed down its cooling. That is why gases, which now intensively evaporate from northern hemisphere, cannot quickly condense in the southern, and keep accumulating in the atmosphere, increasing its pressure. Around 2035–2050, the southern hemisphere will cool enough to permit intensive condensation of the gases, and they will migrate there from the northern hemisphere, where is polar day. It will last till equinox near aphelion (about 2113). The northern hemisphere will not lose its volatile ices completely, and their evaporation will supply the atmosphere even at the aphelion. Overall change of atmospheric pressure in this model is about 4 times; the minimum was reached near 1970–1980, and the maximum near 2030. Full temperature range is only several degrees.[8]

Escape

Atmosphere of Pluto in infrared (New Horizons). The whitish patches are sunlight bouncing off more reflective or smoother areas on Pluto's surface.

Early data suggested that Pluto's atmosphere loses 1027–1028 molecules (50–500 kg) of nitrogen per second, an amount corresponding to the loss of a surface layer of volatile ices several hundred meters or several kilometers thick during the lifetime of the Solar System.[1][6][40] However, subsequent data from New Horizons revealed that this figure was overestimated by at least four orders of magnitude; Pluto's atmosphere is currently losing only 1×1023 molecules of nitrogen and 5×1025 molecules of methane every second. This presumes a loss of several centimeters of nitrogen ice and several dozen meters of methane ice during the lifetime of the Solar System.[10]

Molecules with high enough velocity, which escape into outer space, are ionized by solar ultraviolet radiation. As the solar wind encounters the obstacle formed by the ions, it is slowed and diverted, possibly forming a shock wave upstream of Pluto. The ions are "picked up" by the solar wind and carried in its flow past the dwarf planet to form an ion or plasma tail. The Solar Wind around Pluto (SWAP) instrument on the New Horizons spacecraft made the first measurements of this region of low-energy atmospheric ions shortly after its closest approach on 14 July 2015. Such measurements will enable the SWAP team to determine the rate at which Pluto loses its atmosphere and, in turn, will yield insight into the evolution of the Pluto’s atmosphere and surface.[41]

In September 2016, astronomers announced that the reddish-brown cap of the north pole of Charon, the largest of five moons that orbit Pluto, is composed of tholins, organic macromolecules that may be essential ingredients of life, and produced from methane, nitrogen and related gases released from the atmosphere of Pluto and transferred over about 19,000 km (12,000 mi) distance to the orbiting moon.[11]

History of study

As early as in 1940s, Gerard Kuiper searched evidence for the atmosphere in the spectrum of Pluto,[42] but unsuccessfully.[9] In 1970s, some astronomers considered the hypothesis about thick atmosphere and even oceans of neon: according to some views of those times, all other gases that are abundant in the Solar System would either freeze or escape. However, this hypothesis was based on a heavily overestimated mass of Pluto.[43] No observational data about its atmosphere and chemical composition existed in these days.[9]

First strong, though indirect evidence of the atmosphere appeared in 1976. Infrared photometry on 4-meter Nicholas U. Mayall Telescope revealed on the surface of Pluto methane ice,[44] which must evaporate significantly at Plutonian temperatures.[1]

Existence of the atmosphere of Pluto was proved due to occultations of stars. If the star is occulted by a body without atmosphere, its light disappears sharply, but occultations by Pluto give gradual decrease. This is mainly due to atmospheric refraction (not absorption or scattering).[1][28] First such observations were made 19 August 1985 by Noah Brosch and Haim Mendelson of the Wise Observatory in Israel.[27][45] But quality of the data was rather low due to unfavourable observational conditions (in addition, the detailed description[46] was published only 10 years later).[9] 9 June 1988 existence of the atmosphere was convincingly proved[1] by observations of a new occultation from 8 sites (the best data were obtained by the Kuiper Airborne Observatory). Scale height of the atmosphere was measured, and it gave possibility to calculate ratio of the temperature to mean molecular mass. The temperature and pressure themselves were impossible to calculate in that time due to absence of data about chemical composition of the atmosphere and large uncertainty in radius and mass of Pluto.[26][47][48]

The question about composition was solved in 1992 due to exploring of infrared spectrum of Pluto on 3.8-meter United Kingdom Infrared Telescope.[49][50] The surface of Pluto turned out to be covered mainly by nitrogen ice. Since nitrogen is, in addition, more volatile than methane, this observation implied prevalence of nitrogen also in the atmosphere (although gaseous nitrogen wasn't seen in the spectrum). Beside this, a small admixture of frozen carbon monoxide was discovered.[8][13][49] The same year observations on 3.0-meter NASA Infrared Telescope Facility revealed first conclusive evidence of gaseous methane.[9][23]

For understanding of the state of the atmosphere, knowing of the surface temperature is critically important. Best its estimates are derived from measurements of thermal emission of Pluto. The first values, calculated in 1987 from observations of IRAS, were about 55–60 K, and next works resulted in 30–40 K.[1][9] In 2006, observations on Submillimeter Array succeeded in separating emission of Pluto and Charon, and average temperature of Pluto's surface was measured to be 42±4 K (−231±4°C). It was approximately 10 K colder than expected; maybe, the difference is caused by cooling from sublimation of nitrogen ice.[32][51] The other works revealed that the temperature is strongly different in different regions: from 40 to 55–60 K.[1]

Near 2000, Pluto entered star-rich fields of Milky Way, and will reside there till 2020s. First stellar occultations after 1988 were observed 20 July and 21 August 2002 by teams led by Bruno Sicardy of the Paris Observatory[27] and James L. Elliot of MIT.[28][36] Atmospheric pressure turned out to be about 2 times higher than in 1988. Next occultation was observed 12 June 2006,[7][52] and later they happened more often.[1][4][8][34][53] Processing of this data shows that the pressure continues to increase.[4][8] An occultation of exceptionally bright star, about 10 times brighter than Pluto itself, was observed 29/30 June 2015 – only 2 weeks before New Horizons encounter.[35][54][55]

14 July 2015 the spacecraft New Horizons made first explorations of the atmosphere of Pluto from close distance, including radio occultation measurements and observations of weakening of solar radiation during flight through Pluto's shadow. It provided the first direct measurements of parameters of lower atmosphere. The surface pressure turned out to be 1,0–1,1 Pa.[2][10][38]

X-Rays from Pluto

Notes

  1. Earth-based observations suggested about 0.4–0.6% in 2008[12] and 0.3–0.4% in 2012[5]
  2. At least, in infrared range — from 0.75 to 2 µm.
  3. In these sources this pole is called "south" according to nomenclature of that time.
  4. Square of ratio of distances in aphelion and perihelion: (49.30 au / 29.66 au)2 = 2.76.
  5. Due to reverse direction of axial rotation of Pluto, naming of its poles is somewhat ambiguous. Since 2009, International Astronomical Union defines north (more precisely, positive) pole of Pluto on basis of direction of the rotation: it is that pole, from whose side Pluto appears to rotate counterclockwise (Archinal et al., 2011). It is oriented to southern side of the solar system.

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