TRAPPIST-1b

{{Infobox planet

| name = TRAPPIST-1b

| image = TRAPPIST-1 b comparison.png

| caption = Earth and TRAPPIST-1b compared

| discovery_ref =

| discoverer = Michaël Gillon et al.

| discovery_site = TRAPPIST

| discovered = May 2, 2016

| discovery_method = Transit

| orbit_ref =

| apsis = astron

| aphelion =

| perihelion =

| semimajor = {{convert|0.01154|±|0.00010|AU|km|abbr=on}}

| eccentricity = 0.00622{{±|0.00304}}

| period = {{convert|1.510826|±|0.000006|day|hour|abbr=on}}

| inclination = {{val|89.728|0.165|u=deg}}

| arg_peri = {{val|336.86|34.24|u=deg}}

| star = TRAPPIST-1

| physical_ref =

| mean_radius = {{val|1.116|0.014|0.012|ul=Earth radius}}

| mass = {{val|1.374|0.069|ul=Earth mass}}

| density = {{val|5.425|0.265|0.272|ul=g/cm3}}

| surface_grav = {{val|1.102|0.052}} g
{{val|10.80|0.51|ul=m/s2}}

| albedo = 0.02{{±|0.11}}{{refn|group=lower-alpha|name=albedo1|Best-fit gray albedo}}
0.19{{±|0.08}}

| single_temperature = {{val|397.6|3.8|ul=K}} ({{convert|397.6|K|C F|disp=out}}, equilibrium)
{{val|424|28|ul=K}} ({{convert|424|K|C F|disp=out}}, surface at 12.8 μm)
{{val|478|27|ul=K}} ({{convert|478|K|C F|disp=out}}, surface at 15 μm)

| atmosphere_composition = None or extremely thin
{{chem2|CO2}} (uncertain)

}}

TRAPPIST-1b is a terrestrial, Earth-sized exoplanet orbiting around the ultra-cool dwarf star TRAPPIST-1, located {{Convert|40.7|ly|pc|lk=on|abbr=off}} away from Earth in the constellation of Aquarius. The planet was detected using the transit method, where a planet dims the host star's light as it passes in front of it. It was first announced on May 2, 2016, and later studies were able to refine its physical parameters.

The planet is about 37% more massive than Earth and about 39% larger in volume; thus its density is very similar. It is the innermost of seven planets orbiting TRAPPIST-1, all of which are terrestrial, but is too close to its star to be in the habitable zone. Observations by the James Webb Space Telescope announced between 2023 and 2024 suggest that it is either airless or has a hazy {{chem2|CO2}}-rich atmosphere. Its albedo is very low, making it dark in color.

Physical characteristics

=Mass, radius, and temperature=

TRAPPIST-1b is very similar in both mass, radius, and gravity to Earth. It has a radius of {{val|1.116|ul=Earth radius}}, a mass of {{val|1.374|ul=Earth mass}}, and about 110% Earth's surface gravity. Initial estimates of the planet's density suggested that it is not entirely rocky; with a density of 3.98 g/cm³, about ≤5% of its mass must be volatiles, likely in the form of a thick Venus-like atmosphere due to it receiving nearly four times more energy than Earth does. However, refined density estimates show that the planet is only slightly less dense than Earth.

Assuming the presence of an atmosphere, the planet's surface temperature was initially estimated to be between {{convert|750|K|C F}} and {{convert|1500|K|C F}}, potentially as high as {{convert|2000|K|C F}}. This is much hotter than the surface of Venus and may be hot enough that the surface is molten lava. An observation of the secondary eclipse of TRAPPIST-1b by the James Webb Space Telescope, announced in 2023, suggests that the planet does not have any significant atmosphere, with a measured surface temperature of about {{convert|503|K|C F}}, and a low albedo. The planet may be very geologically active due to tidal squeezing similar to Jupiter's moon Io, which happens to have a similar orbital period and eccentricity (see TRAPPIST-1#Resonance and tides for references).

=Orbit=

TRAPPIST-1b orbits very close to its parent star. One orbit requires only 36 hours, or about 1.51 Earth days. It orbits about {{Convert|0.0115|AU|e6km e6mi|lk=on|abbr=unit}} from its star, just 1.2% the distance between Earth and the Sun. The close proximity to its host star means that TRAPPIST-1b is likely tidally locked. It also has a very circular orbit, with an eccentricity of 0.00622, significantly more circular than Earth's orbit, which has an eccentricity of 0.0167086.

=Host star=

TRAPPIST-1b orbits the ultracool red dwarf star TRAPPIST-1. It has a mass of 0.089 {{Solar_mass}} and is only 0.121 {{Solar_radius}}, with a surface temperature of {{convert|2,511|K|C F}} and an age between 3 and 8 billion years. The Sun, in comparison, has a surface temperature of {{convert|5,778|K|C F}} and is about 4.5 billion years old. TRAPPIST-1 is also very dim, with a luminosity about 0.0005 times that of the Sun. It is too faint to be seen with the naked eye, having an apparent magnitude of 18.80.

=Atmosphere=

File:Rocky exoplanet TRAPPIST-1 b (illustration) (weic2309a).jpg

The combined transmission spectra of TRAPPIST-1 b and c rule out cloud-free hydrogen-dominated atmospheres for both planets, so they are unlikely to harbor extended gas envelopes. Also, no helium emission from TRAPPIST-1b has been detected. Prior to JWST observations, other atmospheres, from a cloud-free water-vapor atmosphere to a Venus-like atmosphere, remained consistent with the featureless spectra.

In 2018, the planet's atmosphere was better examined by the Spitzer Space Telescope and suggested to be quite large and hot, although the presence of an atmosphere could not be confirmed. The planet's transmission spectrum and refined density estimate suggested two main possibilities for the atmosphere: one rich in carbon dioxide, or one rich in water vapor. The more likely CO₂ atmosphere would have a scale height of approximately {{convert|52|km|mi|abbr=off|lk=off|sp=us}} (Earth's being {{convert|8|km|mi|abbr=on|lk=off|sp=us}}, and Venus' at {{convert|15.9|km|mi|abbr=on|lk=off|sp=us}}) and an average temperature in excess of {{convert|1400|K|C F}}, far greater than the planet's equilibrium temperature of {{convert|397.6|K|C F}}. A water vapor atmosphere would need to have a scale height of >{{convert|100|km|mi|abbr=on|lk=off|sp=us}} and a temperature >{{convert|1800|K|C F}} to produce the variations seen in the planet's transit depths and its transmission spectrum, and would be vulnerable to photodissociation where CO₂ would not be. Other sources for the effects seen, such as hazes and thick clouds, would require an even larger atmosphere. TRAPPIST-1b will have to be studied further to confirm its potential large atmosphere.

An observation of the secondary eclipse of TRAPPIST-1b by the James Webb Space Telescope, announced in March 2023, suggested that the planet does not have any significant atmosphere. Atmospheres containing carbon dioxide with surface pressures greater than {{val|0.1|ul=bar}} can be ruled out at 3-sigma, and pressures greater than 0.01 bar at 1-sigma. Further studies of the exoplanet by transmission spectroscopy (primary eclipse), reported in September 2023, also confirmed the absence of a hydrogen-rich atmosphere, but due to stellar contamination were unable to determine the presence or absence of other types of atmospheres based on the transmission spectroscopy data alone. This does not affect the previous results based on emission spectroscopy.

Analysis of 10 secondary eclipses observed by JWST published in December 2024, 5 in 12.8 μm and 5 in 15 μm, showed a shallower eclipse depth in the shorter wavelength that may be caused by photochemical hazes in a thick, {{chem2|CO2}}-rich atmosphere. The presence of photochemical hazes in the atmosphere of TRAPPIST-1 b could create a thermal inversion that warms the upper atmosphere relative to the lower atmosphere, decreasing the infrared brightness temperature at 12.8 μm. The high UV flux of TRAPPIST-1 b would make for efficient photodissociation and photochemistry. However, it is unclear if such hazes can form in a hot, oxidized, {{chem2|CO2}}-rich atmosphere. These results are also compatible with a young ultramafic surface and no atmosphere, which the authors of the 2024 paper slightly favor.

=Geology=

TRAPPIST-1 b has a low albedo of 0.19{{±|0.08}}. The thermal emission at 12.8 μm and 15 μm best fits a surface composition of ultramafic rock (composed of 60% olivine and 40% enstatite). The difference in eclipse depths between the two wavelengths indicates the surface is geologically fresh (≤1000 yrs) and not significantly impacted by space weathering. The presence of fresh ultramafic rock on TRAPPPIST-1 b could indicate recent crustal reprocessing, from volcanic resurfacing or plate tectonics. A combination of tidal heating from the other 6 planets and induction heating from the large magnetic field of its host star should result in a substantial increase in volcanic activity, possibly making TRAPPIST-1 b comparable to Io with a young and crater-free volcanic surface.

Gallery

File:Artist's view of planets transiting red dwarf star in TRAPPIST-1 system.jpg|Artist's view of planets transiting red dwarf star in TRAPPIST-1 system{{cite web|title=Artist's view of planets transiting red dwarf star in TRAPPIST-1 system|url=http://www.spacetelescope.org/images/opo1627a/|website=www.spacetelescope.org|access-date=21 July 2016}}

File:Comparison between the Sun and the ultracool dwarf star TRAPPIST-1.jpg|The Sun and the ultracool dwarf star TRAPPIST-1 to scale. The faint star has only 11% of the diameter of the Sun and is much redder in colour.

File:TRAPPIST-1 and its three planets.jpg|Artist's impression of three of the planets (b, c, and d) orbiting TRAPPIST-1

File:Artist’s impression of the ultracool dwarf star TRAPPIST-1 from close to one of its planets.ogv|Artist's impression video, near one of the three planets orbiting TRAPPIST-1. One of the inner planets is shown in transit across the disc of its tiny and dim parent star.

Notes

References

{{Reflist|refs=

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{{cite web |url=https://webbtelescope.org/contents/news-releases/2023/news-2023-110 |title=NASA's Webb Measures the Temperature of a Rocky Exoplanet |date=27 March 2023 |website=webbtelescope.org |publisher=STScI |access-date=27 March 2023}}

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{{cite news |last=Sherburne |first=Morgan |title=James Webb Space Telescope's first spectrum of a TRAPPIST-1 planet |url=https://phys.org/news/2023-09-james-webb-space-telescope-spectrum.html |date=25 September 2023 |work=Phys.org |url-status=live |archiveurl=https://archive.today/20230929124619/https://phys.org/news/2023-09-james-webb-space-telescope-spectrum.html |archivedate=29 September 2023 |accessdate=29 September 2023 }}

{{cite journal |author=Lim, Olivia |display-authors=et al |title=Atmospheric Reconnaissance of TRAPPIST-1 b with JWST/NIRISS: Evidence for Strong Stellar Contamination in the Transmission Spectra |date=22 September 2023 |journal=The Astrophysical Journal Letters |volume=95 |number=1 |pages=L22 |doi=10.3847/2041-8213/acf7c4 |arxiv=2309.07047 |bibcode=2023ApJ...955L..22L |doi-access=free }}

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}}

Category:Exoplanets discovered in 2016

Category:Near-Earth-sized exoplanets

Category:Transiting exoplanets

Category:TRAPPIST-1

Category:Aquarius (constellation)

J23062928-0502285 b