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TRAPPIST-1c

is a that orbits the ultracool star , an M8-type dwarf located approximately 40 light-years from in the constellation Aquarius. As the second-closest planet to its star in a compact system of seven Earth-sized worlds, it completes one orbit every 2.42 days at a semi-major axis of 0.0158 , with a low of 0.01. The planet has a radius of 1.097 times that of and a mass of 1.308 masses, yielding a density comparable to 's and confirming its , terrestrial composition. Discovered in 2016 through the transit method using ground-based telescopes including the telescope in , TRAPPIST-1c was initially identified alongside planets b and d as part of the first three transiting worlds around this faint star. The full seven-planet system, including refined parameters for TRAPPIST-1c, was confirmed in 2017 via follow-up observations with the and additional ground-based facilities, revealing a resonant orbital chain where planets maintain stable, near-resonant periods. Its radius and mass estimates have been updated over time through transit photometry and transit timing variations (TTVs), which detect gravitational interactions among the planets. Observations by the (JWST) from 2022 to 2025 have provided detailed constraints on TRAPPIST-1c's atmosphere. The 2023 mid-infrared measurements using JWST's instrument ruled out a thick envelope with surface pressures exceeding 0.1 and disfavored Venus-like conditions at 2.6–3.0 sigma confidence. Subsequent 2025 thermal phase curve observations measured a dayside of 369 ± 23 K, with nightside flux statistically consistent with a bare surface, indicating efficient heat redistribution across the tidally locked planet and confirming no thick atmosphere (surface pressure ≥1 ) or efficient . These findings suggest a tenuous, oxygen-dominated atmosphere or an airless surface. Receiving about 2.2 times the stellar irradiation of , TRAPPIST-1c lies near the inner edge of the system's optimistic or outside the conservative but is likely too hot for stable liquid , with models suggesting a runaway greenhouse state if it ever possessed a substantial volatile inventory. This positions it as a Venus analog, offering insights into atmospheric retention around M-dwarf stars and the potential loss of through early stellar activity. The system, including planet c, remains a prime target for studies due to its proximity and the planets' Earth-like sizes, enabling detailed characterization of rocky worlds beyond our solar system. Future JWST observations may further probe for trace gases or surface features, while ground-based efforts continue to refine orbital dynamics and search for additional system properties.

Discovery and naming

Initial detection

TRAPPIST-1c was first detected in 2016 as part of a photometric survey targeting nearby stars using the (TRAnsiting Planets and PlanetesImals Small Telescope), a 0.6-meter robotic installed at the European Southern Observatory's La Silla Observatory in . The survey aimed to identify transiting planets around these dim, cool stars, which are favorable for detecting small, Earth-sized worlds due to the stars' low luminosity and compact radii. The detection relied on transit photometry, which monitors periodic diminutions in the star's brightness caused by a passing in front of it from Earth's perspective. Observations of , conducted over 245 hours from 17 September to 28 December 2015 using an I+z' filter (effective ~885 ), revealed multiple transit-like signals, including a clear 2.42-day periodicity attributed to TRAPPIST-1c. This signal manifested as repeated dips in the light curve, with a depth indicating a roughly Earth-sized relative to the host . To identify these signals, the research team applied the box-fitting (BLS) method, a technique optimized for detecting box-shaped features in light curves by minimizing residuals between the data and a simple rectangular model. The BLS analysis confirmed two strong signals corresponding to planets b (1.51 days) and c (2.42 days), along with a third weaker signal for planet d, amid the star's variable activity. The discovery of these three planets, including TRAPPIST-1c, was announced on May 2, 2016, through a press release and the online publication of the findings in Nature. The small size and cool temperature of the host star TRAPPIST-1 enabled these detections by producing deeper and more observable transit depths compared to hotter stars.

Confirmation and nomenclature

Following the initial detection of TRAPPIST-1c in 2016, its existence was definitively confirmed in early 2017 through intensive photometric monitoring with the . Over a continuous 20-day period in late 2016, the Infrared Array Camera on captured high-precision light curves of multiple transits, enabling the team to rule out false positives like background eclipsing binaries and refine the planet's transit timing variations to within minutes. Complementary ground-based observations further validated the signal. Telescopes including the (VLT) at the , equipped with the HAWK-I instrument, and the United Kingdom Infrared Telescope (UKIRT) detected independent transits of TRAPPIST-1c in the near-infrared, confirming the periodicity and depth of the events while excluding instrumental artifacts or stellar variability as explanations. These multi-site efforts, spanning facilities in and , provided robust corroboration of the Spitzer data. TRAPPIST-1c received its official provisional designation in accordance with (IAU) guidelines for , which assign lowercase letters starting from "b" (with "a" reserved for the host star) based on the order of confirmation around the parent star. As the second verified planet in the system after , it was thus named TRAPPIST-1c to reflect its discovery sequence and orbital position. The confirmation of TRAPPIST-1c, alongside planets b and d from the initial survey, was announced on February 22, 2017, together with the discovery of four additional transiting worlds (designated e, f, g, and h). This revelation of a compact seven-planet system orbiting an star marked a milestone in research, as reported in the peer-reviewed study led by Gillon et al.

The TRAPPIST-1 system

Host star properties

TRAPPIST-1 is an ultracool red dwarf star of spectral type M8V, characterized by its low mass, small radius, and cool effective temperature that result in extremely faint luminosity. As of recent measurements (2023), the star has a mass of 0.0898 ± 0.0023 solar masses and a radius of 0.1192 ± 0.0013 solar radii, making it one of the least massive and smallest known stars hosting a planetary system. Its effective temperature is 2566 ± 26 K, contributing to its classification as an ultracool dwarf with subdued nuclear fusion activity compared to more massive stars. The star's age is estimated at 7.6 ± 2.2 billion years, significantly older than the Solar System, based on kinematic, spectroscopic, and evolutionary indicators that place it in the field population of the . TRAPPIST-1 exhibits a of 5.22 × 10^{-4} solar luminosities, reflecting its inefficient energy output due to the low temperature and small surface area. It is located at a distance of 12.47 parsecs from according to DR3 , allowing detailed observations with current telescopes. Spectral analysis reveals a slightly supersolar with [Fe/H] = +0.04, derived from calibrations. TRAPPIST-1 was first identified in during a survey for nearby ultracool dwarfs using photometry, initially cataloged as 2MASS J23062928−0502285 and noted for high that suggested possible astrometric binary status. High-resolution imaging and astrometric monitoring in 2016 resolved it as a single , confirming no close companion and enabling precise of its . The star's faint luminosity arises from the governed by the Stefan-Boltzmann law: L = 4\pi R^2 \sigma T^4 where L is luminosity, R is the stellar radius, T is the effective temperature, and \sigma = 5.6704 \times 10^{-8} W m^{-2} K^{-4} is the Stefan-Boltzmann constant. Substituting the measured radius and temperature yields the observed low luminosity, emphasizing TRAPPIST-1's dimness relative to Sun-like stars.

Planetary system overview

The TRAPPIST-1 planetary system harbors seven Earth-sized planets, labeled b through h, all orbiting the ultracool dwarf star TRAPPIST-1 in a highly compact configuration. These planets, classified as rocky super-Earths, were first detected in 2016 with the initial three innermost worlds (b, c, and d) identified via ground-based transit photometry, followed by the discovery of the outer four (e, f, g, and h) in 2017 using space-based observations from the Spitzer Space Telescope. The system's architecture is characterized by its extreme proximity to the host star, with all planets confined within approximately 0.06 AU, a radial extent smaller than Mercury's orbit around the Sun (0.39 AU). This compactness arises from the star's low luminosity and cool temperature, which shift the habitable zone inward to permit stable close-in orbits. TRAPPIST-1c occupies the position of the second innermost planet in this arrangement, receiving an incident stellar flux of about 2.27 times that incident on (S⊕). Like its siblings, TRAPPIST-1c and the other planets are expected to be tidally locked due to their short orbital periods and close proximity to the star, resulting in permanent day and night sides. The overall system spans a narrow annular region around the star, fostering frequent gravitational interactions among that shape their dynamics. A defining feature of the TRAPPIST-1 system is its chain of mean-motion orbital resonances, where the planets' periods align in ratios such as 8:5 between b and c, 5:3 between c and d, 3:2 between d and e, and similar patterns extending outward. This resonant configuration, likely established during the planets' formation and , provides mutual gravitational perturbations that dampen instabilities and maintain the system's integrity. Dynamical simulations indicate that these resonances have stabilized the orbits for at least a billion years, with the potential for even longer-term survival comparable to the age of the solar system.

Orbital characteristics

Orbital path and period

TRAPPIST-1c orbits its host star at a semi-major axis of 0.01580 ± 0.00013 , placing it in a close-in trajectory that results in an of 2.421937 ± 0.000018 days. This short period corresponds to approximately 58.1 hours per complete orbit, reflecting the compact nature of the system where all known planets reside within 0.06 of the star. The is nearly circular, with an of less than 0.01, indicating minimal deviation from a perfect and contributing to stable orbital dynamics over long timescales. The orbital inclination relative to the sky plane is 89.778 ± 0.118 degrees, which enables the planet to its star as viewed from , allowing for precise measurements of its path geometry through photometric observations. Due to the proximity to the star, TRAPPIST-1c is expected to be in a 1:1 spin- resonance, meaning it is tidally locked with one hemisphere permanently facing the star. These orbital parameters adhere to Kepler's third law, adapted for the TRAPPIST-1 system as P^2 = \frac{4\pi^2}{G(M_\star + m_p)} a^3 \approx \frac{4\pi^2}{G M_\star} a^3, where P is the , a is the semi-major axis, M_\star is the (approximately 0.089 M_\odot), and m_p is the (negligible compared to M_\star). Substituting the measured values yields the observed of roughly 2.42 days, confirming the consistency of the with gravitational dynamics in this low-mass stellar environment. Transits of TRAPPIST-1c produce a photometric depth of 0.7123 ± 0.0064% in the star's , with a full duration (from first to fourth ) of 0.7005 ± 0.0022 hours, or about 42 minutes. These characteristics facilitate high-precision timing of events, essential for refining the orbital and detecting potential perturbations from the system's resonant chain.

Dynamical interactions

TRAPPIST-1c is part of a Laplace chain involving the inner planets b, c, and d, where their orbital periods maintain an approximate ratio of 24:15:9. This three-body configuration contributes significantly to the long-term orbital stability of these planets by synchronizing their gravitational perturbations and preventing chaotic disruptions. Simulations of the system's formation indicate that the planets, including TRAPPIST-1c, likely originated farther from the host star in the and underwent inward driven by disk-star interactions. During this convergent , the planets captured their current resonant chain, with the process occurring primarily within the disk's lifetime of a few million years, allowing the configuration to persist through the system's age of approximately 7.6 billion years. Tidal dissipation within the star could potentially lead to gradual for the inner planets, including TRAPPIST-1c, by transferring from the orbits to the star's spin. However, current dynamical models incorporating effects predict that the resonant will maintain for at least another billion years, with minimal changes to the orbital . N-body simulations demonstrate that gravitational interactions with neighboring planets e and f result in low levels of eccentricity excitation for TRAPPIST-1c, typically keeping variations below 0.01 due to the damping effects of the overall resonant structure. These simulations confirm the robustness of the against perturbations from outer planets, ensuring dynamical equilibrium over gigayear timescales.

Physical properties

Size, mass, and density

The of TRAPPIST-1c has been measured to be $1.097 \pm 0.014 radii through modeling of s observed primarily with the , employing quadratic limb-darkening laws to account for the host star's atmospheric effects on the light curve shape. These measurements rely on the transit depth, which scales with the square of the planet-to-star ratio and is influenced by the host star's of approximately $0.119 R_⊙ (solar radii). The of TRAPPIST-1c is $1.308 \pm 0.056 masses, determined by combining measurements from the HARPS and spectrographs with constraints from transit timing variations (TTV) analyzed via N-body dynamical modeling of 447 transit epochs. The TTV method exploits gravitational interactions among the s to infer masses, with timing precisions reaching about 0.5 minutes for this , enabling mass determinations to 3–5% accuracy when augmented by radial velocities equivalent to 2.5 cm/s precision. The of TRAPPIST-1c is calculated as approximately 5.45 g/cm³ using the for a sphere's , \rho = \frac{3M}{4\pi R^3}, where M and R are the planet's and , respectively; this value, with an uncertainty of about ±0.23 g/cm³, is consistent with a rocky featuring an iron core and , akin to Earth-like terrestrial planets.

Surface conditions and composition

TRAPPIST-1c is inferred to possess a differentiated interior structure, consisting of an iron-rich core comprising approximately 30% of its and a surrounding making up the remaining 70%, akin to Earth's but potentially enriched in volatiles due to the planet's formation . These models rely on the planet's measured of 5.45 ± 0.23 g/cm³, derived from and observations, to constrain the internal layering using equations of state for rocky and metallic materials. The planet's surface gravity is estimated at 1.1 times that of (approximately 10.7 m/s²), which arises from its mass of about 1.3 Earth masses and radius of 1.1 Earth radii. This level of is sufficient to retain a and potentially enable geological processes, such as , if sustained by internal heat sources like dissipation from the planet's close and resonant interactions within the . Interior models predict localized points in the mantle under stresses, using of state to assess in rocks. No direct observations of the surface exist due to the planet's distance and small size, but compositional models suggest low water content, with mantle water fractions around 0.4 wt% (up to ~1 wt%), as recent geochemical models indicate median mantle water solubility around 0.4 wt%, potentially available for outgassing but insufficient for a subsurface ocean or thick vapor envelope given recent atmospheric constraints. These estimates stem from integrating density constraints with volatile delivery models during accretion, indicating higher volatile content than Earth but subject to loss mechanisms like impacts and irradiation. Recent geochemical analyses further refine mantle water solubility to medians around 0.4 wt%, supporting limited but plausible hydration that could influence surface evolution through outgassing.

Atmosphere and climate

Atmospheric composition studies

Early observations of TRAPPIST-1c's potential atmosphere were conducted using the Hubble Space Telescope's (WFC3) in , capturing a combined transmission during a simultaneous of b and c in the near-infrared (1.1–1.7 μm). The flat , lacking any detectable absorption features, ruled out cloud-free hydrogen-dominated atmospheres at greater than 10σ confidence for TRAPPIST-1c, implying an upper limit of less than 0.1% of the planet's mass for any H/He envelope if present. Subsequent observations with the (JWST) employed the Near-Infrared Imager and Slitless Spectrograph (NIRISS) in single-object slitless spectroscopy (SOSS) mode to observe two transits of TRAPPIST-1c, one in October 2022 and another in October 2023, spanning wavelengths from 0.6 to 2.85 μm. The resulting transmission spectrum showed no detectable features attributable to H₂O, CO₂, or CH₄, with all variations consistent with stellar from spots and faculae at levels of 100–500 ppm. After correcting for this , the data rule out thick (greater than 0.1 bar), clear hydrogen-dominated atmospheres at better than 3σ confidence and place strict upper limits on molecular feature depths below 100 ppm. Theoretical models indicate that intense stellar XUV irradiation would strip any primary H/He atmosphere from TRAPPIST-1c, potentially leaving a secondary atmosphere dominated by N₂ or resulting in a bare rock surface. Analyses incorporating the JWST data constrain the of any such secondary atmosphere to less than 0.01 atmospheres, as thicker compositions would produce detectable spectral features exceeding the observed limits. These constraints rely on spectroscopy, where variations in transit depth with probe atmospheric extent. The depth variation for spectral features is approximated by \delta_\lambda \approx 2 \frac{R_p}{R_*} n_H \frac{H}{R_*}, where R_p and R_* are the planetary and stellar radii, n_H is the number of scale heights over which the atmosphere is opaque at that wavelength, and H is the atmospheric scale height; this relation sets the <100 ppm limits on undetectable features for TRAPPIST-1c.

Temperature and equilibrium models

The equilibrium temperature of TRAPPIST-1c is derived from the incident stellar radiation and planetary properties using the formula for a rapidly rotating planet: T_{\rm eq} = T_{\star} \sqrt{\frac{R_{\star}}{2a}} (1 - A)^{1/4}, where T_{\star} is the effective temperature of the host star, R_{\star} its radius, a the orbital semi-major axis, and A the Bond albedo. Assuming zero albedo (A = 0), this yields T_{\rm eq} \approx 342 K, corresponding to the planet receiving approximately 2.21 times the bolometric insolation flux of Earth. For a Bond albedo of 0.3 typical of rocky planets without significant reflective clouds or ices, the effective temperature decreases to approximately 315 K. Due to its close orbit (period of 2.42 days), TRAPPIST-1c is expected to be tidally locked, leading to inhomogeneous heating and the need for models that account for limited heat redistribution. One-dimensional radiative-convective equilibrium (RCE) models simulate the thermal structure by balancing absorbed stellar flux with , incorporating atmospheric opacity and . These models assume a substellar dayside receiving full insolation and a nightside with no direct heating, connected by atmospheric . In such 1D RCE simulations for TRAPPIST-1c with thin atmospheres (e.g., 0.1 bar O₂-dominated with trace CO₂ and surface of 0.1), the dayside surface reaches up to approximately 400 , while the nightside remains cooler at around 200–350 , depending on heat transport efficiency. For bare-rock scenarios or negligible atmospheres, the dayside aligns closely with the no-redistribution equilibrium value of about 370–400 , highlighting the planet's hot thermal environment. Greenhouse effects from potential thin atmospheres can elevate surface temperatures above the effective value by 50–100 on the dayside, but efficient circulation may moderate nightside cooling. Recent JWST/MIRI observations at 15 μm in 2025 obtained the first thermal phase curve of TRAPPIST-1c, measuring a dayside of 369 ± 23 K and a nightside flux of 62^{+60}_{-43} ppm relative to the dayside, indicating inefficient heat redistribution consistent with a bare rock surface or a tenuous atmosphere. These data disfavor thick atmospheres (≥1 surface pressure) with strong effects and support scenarios with a greenhouse-poor O₂-dominated secondary atmosphere or no substantial atmosphere.

Observational history and future prospects

Key telescope observations

Following the initial detection of transits using the ground-based in 2016, subsequent space-based observations provided critical confirmation and refinement of the orbital parameters for TRAPPIST-1c. In early 2017, NASA's , operating in its mission's Campaign 12, monitored the system for 79 days, capturing multiple transits of TRAPPIST-1c and the other planets amid the host star's low-amplitude variability, which was modeled using Gaussian processes to achieve precise photometry. The Spitzer Space Telescope conducted intensive follow-up campaigns from 2017 through 2018 and beyond, accumulating extensive photometric data essential for transit timing variation (TTV) studies. Early observations in February and March 2017 alone yielded 60 new transits across the system, including several for TRAPPIST-1c, enabling initial refinements to orbital ephemerides and planetary radii with sub-5% precision. Over four years of Spitzer monitoring (up to 2020), combined with ground-based, Hubble Space Telescope, and K2 data, TTV analyses refined the masses of TRAPPIST-1c and its siblings to 3–5% precision, equivalent to a radial-velocity accuracy of 2.5 cm/s, while confirming the resonant chain dynamics. The Transiting Exoplanet Survey Satellite (TESS) contributed additional transits in its Sector 3 observations during 2018, detecting clear signals for TRAPPIST-1c despite the short 27-day baseline, and further data in later sectors including 2023, which helped mitigate long-term ephemeris drift and supported updated TTV models. Beginning in 2023, the James Webb Space Telescope (JWST) targeted TRAPPIST-1c with its Near-Infrared Imager and Slitless Spectrograph (NIRISS) in single-object slitless spectroscopy mode, observing two transits to probe transmission spectra from 0.6 to 2.85 μm; these yielded flat spectra with no detectable molecular absorption features, imposing strict upper limits on atmospheric scale heights and constraining hydrogen- or water-dominated envelopes to less than 0.3% of the planet's radius. Complementary JWST/NIRSpec prism observations in 2023–2024 extended coverage to 0.6–5.5 μm across multiple transits, again finding featureless spectra that rule out thick CO₂-rich atmospheres and favor bare-rock or thin-atmosphere scenarios, with ongoing analyses as of 2025. For thermal emission, JWST's Mid-Infrared Instrument (MIRI) low-resolution spectrometer captured secondary eclipses in 2022 at 15 μm, detecting a broadband signal consistent with a dayside brightness temperature of 380 ± 31 K and low albedo. In September 2025, JWST MIRI observed a full phase curve at 15 μm, yielding a dayside brightness temperature of 369 ± 23 K, confirming efficient but limited heat redistribution and ruling out thick atmospheres with surface pressures ≥1 bar. Further MIRI LRS campaigns are ongoing into 2025 to map additional phase curves. Ground-based preparations for high-resolution spectroscopy include modeling for the Extremely Large Telescope (ELT), where instruments like ANDES are expected to resolve atmospheric signals in reflected light for TRAPPIST-1c at R ≈ 100,000, simulating detection of biomarkers or haze in visible-to-near-infrared spectra.

Planned missions and studies

The James Webb Space Telescope (JWST) continues to target the TRAPPIST-1 system in Cycle 4 (2025–2026) and Cycle 5 (2026–2027), with planned transit observations to refine atmospheric constraints on TRAPPIST-1c and its siblings. An updated ephemeris forecast provides transit timing predictions with uncertainties as low as 7 seconds, facilitating precise scheduling for spectroscopy that could detect molecular features at sensitivities approaching 50 parts per million. The Ariel Space Telescope, an ESA-led mission set for launch in 2029, will perform a comprehensive survey of about 1,000 atmospheres, including rocky worlds in the system. Phase-curve observations with Ariel's photometric and spectroscopic channels will map thermal structures and search for volatile species, offering insights into heat redistribution and potential atmospheric retention on TRAPPIST-1c despite the host star's flares. This capability complements JWST by providing statistical context across diverse exoplanets. The (ELT), anticipated to achieve first light in 2028, will employ high-resolution cross-correlation spectroscopy via instruments like to probe trace gases in terrestrial atmospheres. For TRAPPIST-1c, this could enable detection of candidates such as O₂ or (DMS) at parts-per-billion levels, overcoming limitations of space-based telescopes in resolving faint signals amid stellar activity. ELT's 39-meter positions it as a key ground-based facility for confirming indicators on nearby systems like TRAPPIST-1. Theoretical modeling in 2025 has advanced predictions for TRAPPIST-1c's detectability, incorporating updated energy balance models for tidally locked planets. These studies suggest a index near 0.8 under scenarios with a thin CO₂-dominated atmosphere, though stellar flares pose significant challenges to volatile retention and observational clarity. Such models emphasize the planet's potential for runaway greenhouse conditions, informing target prioritization for upcoming missions.

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