TRAPPIST-1 is orbited by seven planets, designated
TRAPPIST-1b,
1c,
1d,
1e,
1f,
1g and
1h in alphabetic order going out from the star. These planets have orbital periods ranging from 1.5 to 19 days, at distances of 0.011–0.059 astronomical units (1.7–8.9 million km). All the planets are much closer to their star than
Mercury is to the Sun, with the distance between TRAPPIST-1b and 1c at
syzygy being only twice that between the Earth and Moon, making the TRAPPIST-1 system very compact. Kral
et al. (2018) did not detect any
comets around TRAPPIST-1, and Marino
et al. (2020) found no evidence of a
Kuiper belt, although it is uncertain whether a Solar System-like belt around TRAPPIST-1 would be observable from Earth. Observations with the
Atacama Large Millimeter Array found no evidence of a
circumstellar dust disk. The inclinations of planetary orbits relative to each other are less than 0.1 degrees, making TRAPPIST-1 the flattest planetary system in the
NASA Exoplanet Archive. The orbits are highly circular, with minimal
eccentricities and are well aligned with the spin axis of TRAPPIST-1. The planets orbit in the same plane and, from the perspective of the Solar System, transit TRAPPIST-1 during their orbit and frequently pass in front of each other.
Size and composition The radii of the planets are estimated to range between 77.5% and 112.9% of Earth's radius. The planet/star mass ratio of the TRAPPIST-1 system resembles that of the moon/planet ratio of the Solar System's
gas giants. The TRAPPIST-1 planets are expected to have compositions that resemble each other as well as that of Earth. The estimated densities of the planets are lower than Earth's which may imply that they have large amounts of
volatile chemicals. Alternatively, their cores may be smaller than that of Earth and therefore they may be rocky planets with less iron than that of Earth, include large amounts of elements other than iron, or their iron may exist in an oxidised form rather than as a core. Their densities are too low for a pure
magnesium silicate composition, requiring the presence of lower-density compounds such as water. Planets b, d, f, g and h are expected to contain large quantities of volatile chemicals. The planets may have deep atmospheres and oceans, and contain vast amounts of ice.
Subsurface oceans, buried under icy shells, would form in the colder planets. Several compositions are possible considering the large uncertainties in their densities. The photospheric features of the star may introduce inaccuracies in measurements of the properties of TRAPPIST-1's planets, including their densities being underestimated by 8 per cent, and incorrect estimates of their water content.
Resonance and tides The planets are in
orbital resonances. The durations of their orbits have ratios of 8:5, 5:3, 3:2, 3:2, 4:3 and 3:2 between neighbouring planet pairs, and each set of three is in a
Laplace resonance.
Simulations have shown such resonances can remain stable over billions of years but that their stability is strongly dependent on initial conditions. Many configurations become unstable after less than a million years. The resonances enhance the exchange of
angular momentum between the planets, resulting in measurable variations—earlier or later—in their transit times in front of TRAPPIST-1. These variations yield information on the planetary system, such as the masses of the planets, when other techniques are not available. The resonances and the proximity to the host star have led to comparisons between the TRAPPIST-1 system and the
Galilean moons of Jupiter.
Kepler-223 is another exoplanet system with a TRAPPIST-1-like long resonance. The closeness of the planets to TRAPPIST-1 results in
tidal interactions stronger than those on Earth. All the planets have reached an equilibrium with slow planetary rotations and
tidal locking, which can lead to the synchronisation of a planet's rotation to its revolution around its star. However, interactions among the planets could prevent them from reaching full synchronisation, which would have important implications for the planets' climates. These interactions could force periodic or episodic full rotations of the planets' surfaces with respect to the star on timescales of several Earth years. Vinson, Tamayo and Hansen (2019) found the planets TRAPPIST-1d, e and f likely have
chaotic rotations due to mutual interactions, preventing them from becoming synchronised to their star. Lack of synchronisation potentially makes the planets more habitable. Other processes that can prevent synchronous rotation are
torques induced by stable
triaxial deformation of the planets, which would allow them to enter 3:2 resonances. The planets are likely to undergo substantial
tidal heating due to deformations arising from their orbital eccentricities and gravitational interactions with one another. Such heating would facilitate volcanism and
degassing especially on the innermost planets, with degassing facilitating the establishment of atmospheres. According to Luger
et al. (2017), tidal heating of the four innermost planets is expected to be greater than
Earth's inner heat flux. For the outer planets Quick
et al. (2020) noted that their tidal heating could be comparable to that in the Solar System bodies
Europa,
Enceladus and
Triton, and may be sufficient to drive detectable
cryovolcanic activity. On the other hand, Thomas
et al. (2025) assumed that the constraints on atmospheric composition imply that volcanic activity on most TRAPPIST-1 planets would be less than on Earth. Tidal heating could influence temperatures of the night sides and
cold areas where volatiles may be trapped, and gases are expected to accumulate; it would also influence the properties of any subsurface oceans where
cryovolcanism,
volcanism and
hydrothermal venting could occur. It may further be sufficient to melt the
mantles of the four innermost planets, in whole or in part, potentially forming subsurface magma oceans. This heat source is likely dominant over
radioactive decay, both of which have substantial uncertainties and are considerably less than the stellar radiation received. Intense tides could fracture the planets'
crusts even if they are not sufficiently strong to trigger the onset of
plate tectonics. Tides can also occur in the
planetary atmospheres.
Skies and impact of stellar light of the Solar System|alt=TRAPPIST-1 planets are of similar or smaller size than Earth and have similar or smaller densities|upright=2 Because most of TRAPPIST-1's radiation is in the infrared region, there may be very little visible light on the planets' surfaces; Amaury Triaud, one of the system's co-discoverers, said the skies would never be brighter than Earth's sky at sunset and only a little brighter than a night with a
full moon. Ignoring atmospheric effects, illumination would be orange-red. For TRAPPIST-1e, the central star would be four times as wide in the sky as the Sun in Earth's. All of the planets would be visible from each other and would, in many cases, appear larger than Earth's Moon in the sky of Earth, and each would be recognisable as a planet rather than a star. They would undergo noticeable
retrograde motions in the sky. Observers on TRAPPIST-1e, f and g, however, could never experience a total
stellar eclipse. Assuming the existence of atmospheres, the star's long-wavelength radiation would be absorbed to a greater degree by water and carbon dioxide than sunlight on Earth; it would also be scattered less by the atmosphere and less reflected by ice, although the development of highly reflective
hydrohalite ice may negate this effect. The same amount of radiation results in a warmer planet compared to Sun-like
irradiation; more radiation would be absorbed by the planets' upper atmosphere than by the lower layers, making the atmosphere
more stable and less prone to
convection.
Habitable zone s of TRAPPIST-1 and the
Solar System. The displayed planetary surfaces are speculative. For a dim star like TRAPPIST-1, the
habitable zone is located closer to the star than for the Sun. Three or four planets might be located in the habitable zone; these include , and ; or , and . , this is the largest-known number of planets within the habitable zone of any known star or
star system. The presence of liquid water on any of the planets depends on several other factors, such as
albedo (reflectivity), the presence of an atmosphere, and any
greenhouse effect. Surface conditions are difficult to constrain without better knowledge of the planets' atmospheres. A synchronously rotating planet might not entirely freeze over if it receives too little radiation from its star because the day-side could be sufficiently heated to halt the progress of
glaciation. Other factors for the occurrence of liquid water include the presence of oceans and vegetation; the reflective properties of the land surface; the configuration of continents and oceans; the presence of clouds; and
sea ice dynamics. The effects of volcanic activity may extend the system's habitable zone to TRAPPIST-1h. Even if the outer planets are too cold to be habitable, they may have ice-covered subsurface oceans that may harbour life. Intense
extreme ultraviolet (XUV) and
X-ray radiation can
split water into hydrogen and oxygen, and heat the upper atmosphere until they escape from the planet. This was thought to have been particularly important early in the star's history, when radiation was more intense and could have heated every planet's water to its boiling point. This process is believed to have driven water from
Venus. In the case of TRAPPIST-1, different studies with different assumptions on the
kinetics,
energetics and XUV emissions have come to different conclusions on whether any TRAPPIST-1 planet may retain substantial amounts of water. Because the planets are most likely synchronised to their host star, any water present could become trapped on the planets' night sides and would be unavailable to support life unless heat transport by the atmosphere or tidal heating are intense enough to melt ice.
Moons No
moons with a size comparable to Earth's have been detected in the TRAPPIST-1 system, and they are unlikely in such a densely packed planetary system. This is because moons would likely be either destroyed by their planet's gravity after entering its
Roche limit or stripped from the planet by leaving its
Hill radius Although the TRAPPIST-1 planets appear in an analysis of potential
exomoon hosts, they do not appear in the list of habitable-zone exoplanets that could host a moon for at least one
Hubble time, a timeframe slightly longer than the current age of the Universe. Despite these factors, it is possible the planets could host moons.
Magnetic effects The TRAPPIST-1 planets are expected to be within the
Alfvén surface of their host star, the area around the star within which any planet would directly magnetically interact with the
corona of the star, possibly destabilising any atmosphere the planet has. Stellar energetic particles would not create a substantial
radiation hazard for organisms on TRAPPIST-1 planets if atmospheres reached pressures of about . Estimates of radiation fluxes have considerable uncertainties due to the lack of knowledge about the structure of TRAPPIST-1's magnetic field.
Induction heating from the star's time-varying electrical and magnetic fields may occur on its planets but this would make no substantial contribution to their energy balance and is vastly exceeded by tidal heating.
Formation history The TRAPPIST-1 planets most likely formed farther from the star and
migrated inward, although it is possible they formed in their current locations. According to the most popular theory on the formation of the TRAPPIST-1 planets (Ormel
et al. (2017)), the planets formed when a
streaming instability at the
water-ice line gave rise to
precursor bodies, which accumulated additional fragments and migrated inward, eventually giving rise to planets. The migration may initially have been fast and later slowed, and tidal effects may have further influenced the formation processes. The distribution of the fragments would have controlled the final mass of the planets, which would consist of approximately 10% water, consistent with observational inference. Resonant chains of planets like those of TRAPPIST-1 usually become unstable when the gas disk that gave rise to them dissipates but, in this case, the planets remained in resonance. The resonance may have been either present from the system's formation and was preserved when the planets simultaneously moved inward, or it might have formed later when inward-migrating planets accumulated at the outer edge of the gas disk and interacted with each other. Inward-migrating planets would contain substantial amounts of water—too much for it to entirely escape—whereas planets that formed in their current location would most likely lose all water. According to Flock
et al. (2019), the orbital distance of the innermost planet TRAPPIST-1b is consistent with the expected radius of an inward-moving planet around a star that was one order of magnitude brighter in the past, and with the cavity in the
protoplanetary disc created by TRAPPIST-1's magnetic field. Alternatively, TRAPPIST-1h may have formed in or close to its current location. The presence of other bodies and
planetesimals early in the system's history would have destabilised the TRAPPIST-1 planets' resonance if the bodies were massive enough. Raymond
et al. (2021) concluded the TRAPPIST-1 planets assembled in one to two million years, after which time little additional mass was accreted. This would limit any late delivery of water to the planets and also implies the planets
cleared the neighbourhood of any additional material. The lack of giant
impact events (the rapid formation of the planets would have quickly exhausted pre-planetary material) would help the planets preserve their volatile materials, only once the planet formation process was complete. Due to a combination of high irradiation, the greenhouse effect of water vapour atmospheres, and remnant heat from the process of planet assembly, the TRAPPIST-1 planets would likely have initially had molten surfaces. Eventually the surfaces would cool until the magma oceans solidified, which in the case of TRAPPIST-1b may have taken between a few billions of years, or a few millions of years. The outer planets would then have become cold enough for water vapour to condense. == List of planets ==