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WASP-96b
WASP-96b
WASP-96b
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WASP-96b
Light curve of star WASP-96 during transit of WASP-96b, taken by the James Webb Space Telescope
Discovery[1]
Discovered byHellier et al. (WASP)
Discovery dateOctober 2013
Transit
Orbital characteristics[2]
0.0454±0.0013 AU
Eccentricity<0.11
3.4252602(27) d
Inclination85.60°±0.20°
Semi-amplitude64.0+5.3
−4.8 m/s
Physical characteristics[2]
1.200±0.060 RJ
Mass0.490+0.049
−0.047 MJ
Mean density
0.352+0.068
−0.059 g/cm3
Temperature1285 K[1]

WASP-96b is a gas giant exoplanet. Its mass is 0.48 times that of Jupiter. It is 0.0453 AU from the class G star WASP-96, which it orbits every 3.4 days. It is about 1,140 light-years away from Earth, in the constellation Phoenix. It was discovered in 2013 by the Wide Angle Search for Planets (WASP).

WASP-96b orbits its Sun-like star WASP-96 every 3.4 Earth days at a distance just one-ninth of the distance between Mercury and the Sun.[3]

The hot-Jupiter exoplanet was found via the transiting method by Coel Hellier et.al. in 2013 as part of the WASP-South survey.[1]

Atmosphere

[edit]
Spectrum of WASP-96b, as captured by the James Webb Space Telescope

WASP-96b's spectrum was one of the images featured in the initial science release from the James Webb Space Telescope in July 2022.[4] The spectrum confirmed the presence of water, as well as providing evidence for "clouds and hazes" within the planet's atmosphere.[3] Prior to this discovery, WASP-96b was thought to be free of clouds.[5][6]

While the light curve released confirms properties of the planet that had already been determined from other observations – the existence, size, and orbit of the planet – the transmission spectrum revealed previously hidden details of the atmosphere: the unambiguous signature of water, indications of haze, and evidence of clouds that were suspected based on prior observations.[7]

A study in 2023 measured the abundance of certain chemical species in the atmosphere of WASP-96b as seen in the table below.[8] Models of the atmosphere with patchy clouds and hazes best describes the observations through the James Webb Space Telescope.[8]

Chemical Species[8] log(VMR)[8] Concentration
Water vapor -3.59+0.35
−0.35 		257 ppm
Carbon monoxide -3.25+0.91
−5.06 		562 ppm
Carbon dioxide -4.38+0.47
−0.57 		41.7 ppm
Sodium -6.85+2.48
−3.10 		141 ppb
Potassium -8.04+1.22
−1.71 		9.12 ppb

See also

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

WASP-96b

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from Grokipedia
WASP-96b is a hot Saturn-mass that transits its host star, a G8-type dwarf located approximately 1,150 light-years away in the constellation Phoenix. Discovered in 2014 through the transit method by the (WASP) project, with confirmation via observations from the Euler and TRAPPIST telescopes, the planet has a mass of 0.48 ± 0.03 masses and a radius of 1.20 ± 0.06 radii. It orbits every 3.425 days at a semi-major axis of 0.045 AU, resulting in an equilibrium of approximately 1,300 due to intense stellar irradiation. This close-in orbit classifies WASP-96b as a "hot Saturn," with a low eccentricity near zero, and its host star exhibits a of [Fe/H] = +0.14 ± 0.19. The planet's atmosphere is characterized by a sodium-rich composition, initially hinted at through ground-based observations. It features a hazy structure with no evidence for a uniform grey cloud deck. In July 2022, the (JWST) targeted WASP-96b during its Early Release Observations using the Near-Infrared Imager and Slitless Spectrograph (NIRISS) in Single-Object Slitless Spectroscopy (SOSS) mode, yielding the mission's first detailed transmission spectrum of an atmosphere. This spectrum provided unambiguous detection of absorption features, along with evidence for enhanced or pressure-broadened sodium lines at shorter wavelengths. Retrieval analyses indicate a of 1 to 5 times solar and a carbon-to-oxygen ratio consistent with solar values, highlighting WASP-96b's potential for further studies of in hot exoplanets.

Discovery

Initial detection

The (WASP) project is a ground-based photometric survey designed to detect transiting exoplanets around bright stars, employing wide-field cameras to monitor large sky areas for periodic dips in stellar brightness indicative of planetary transits. WASP-South, one of the project's twin arrays located in , uses eight 200 mm f/1.8 cameras to observe the sky with a of approximately 10 minutes, targeting stars with visual magnitudes between 9 and 13 to identify short-period companions. WASP-96, a G8-type star, was monitored photometrically by WASP-South between June 2010 and December 2011, yielding over 13,100 data points in its . The initial detection of WASP-96b occurred through automated transit searches applied to these accumulated light curves, revealing repeated transit events that suggested the presence of a short-period companion orbiting every few days. Preliminary analysis of the transit shape and depth indicated a Jupiter-sized candidate transiting a solar-like host. The candidacy of WASP-96b was announced in 2014 as part of a broader report on seven new transiting hot Jupiters discovered by the WASP consortium. From the fitting, the initial was estimated at 3.4252602 ± 0.0000027 days, with the transit duration spanning about 2.5 hours and a depth of roughly 1.5%, consistent with a large planetary radius relative to the star. These efforts led to subsequent confirmation through measurements.

Confirmation and naming

Following the initial photometric detection of a transit signal, confirmation of WASP-96b as an exoplanet required spectroscopic follow-up to measure the host star's radial velocity variations induced by the gravitational influence of the orbiting body. Additional photometric follow-up observations were obtained with the TRAPPIST telescope to confirm the transit events. Radial velocity observations were obtained using the CORALIE high-resolution spectrograph mounted on the 1.2-meter Euler Swiss Telescope at La Silla Observatory in Chile, spanning from October 2011 to October 2012 with a total of 21 measurements. These data detected a periodic stellar wobble with a semi-amplitude of approximately 62 m/s, consistent with a low-mass companion rather than a binary star system. From these measurements, combined with the transit-derived inclination, the mass of the planet was calculated as 0.48 ± 0.03 masses, providing definitive evidence of its planetary nature and ruling out false positives such as eclipsing binaries. The was officially designated WASP-96b, adhering to the International Astronomical Union's conventions for naming discoveries from the (WASP) survey, where the survey acronym is followed by a sequential number for the host star and lowercase letters (starting with 'b') for orbiting planets. These findings, including the radial velocity analysis and confirmation, were detailed in a paper published in the Monthly Notices of the Royal Astronomical Society in May 2014 by Hellier et al.

Host star

Physical properties

WASP-96 is a G8V main-sequence star, classified as a slightly cooler analog to the Sun with an of 5500 ± 150 K derived from high-resolution . This places it cooler than the solar value of approximately 5772 K, consistent with its spectral type. The star's is mildly supersolar at [Fe/H] = +0.14 ± 0.19 dex, also determined spectroscopically using the CORALIE instrument on the Euler Telescope. The stellar mass is estimated at 1.06 ± 0.09 M_⊙ through (MCMC) modeling that incorporates and transit data alongside models. Similarly, the radius measures 1.05 ± 0.05 R_⊙ from the same analysis. , log g = 4.25 ± 0.15 (in cgs units), stems directly from spectroscopic measurements, while the projected rotational velocity is low at v sin i = 1.5 ± 1.3 km/s, indicating a relatively slow rotator. is derived as log(L/L_⊙) ≈ -0.04, yielding about 0.91 L_⊙, based on the and radius.
PropertyValueUncertaintyMethod/Source
Spectral typeG8V-Spectroscopy
Effective temperature5500 K±150 KSpectroscopy
Mass1.06 M_⊙±0.09 M_⊙MCMC + evolution models
Radius1.05 R_⊙±0.05 R_⊙MCMC + evolution models
Surface gravity4.25 (log g, cgs)±0.15Spectroscopy
Metallicity+0.14 dex±0.19 dexSpectroscopy
Luminosity0.91 L_⊙-Derived from T_eff and R_⊙
Age estimates for WASP-96 vary between methods: gyrochronology suggests approximately 8^{+26}_{-8} Gyr, while abundance implies a younger 2–5 Gyr. These properties render WASP-96 a stable, Sun-like host conducive to transit observations.

Observational

The (WASP) survey conducted systematic photometric monitoring of the southern sky from 2004 to 2011 using wide-field cameras to identify transiting candidates through periodic dips in stellar brightness. For the star WASP-96, targeted observations were performed with the WASP-South array, consisting of eight 200-mm f/1.8 cameras, from June 2010 to December 2011, accumulating around 100 data points at a typical of 10 minutes. These measurements revealed no significant rotational modulation in the star's , with variability limited to less than 1 mmag at 95% confidence. Following the identification of a potential transit signal, post-discovery follow-up included high-resolution to measure radial velocities and constrain stellar atmospheric parameters. Observations were obtained with the CORALIE echelle spectrograph on the 1.2-m Euler at from October 2011 to October 2012, yielding 21 spectra with a of about 100:1 when co-added. Analysis of these spectra via excitation and ionization balance of iron lines provided estimates of the (5500 ± 150 K), (log g = 4.25 ± 0.15), and ([Fe/H] = +0.14 ± 0.19). The European Space Agency's mission delivered precise astrometric data in its Data Release 3 (2022), confirming WASP-96's position in the constellation Phoenix at a distance of approximately 1150 light-years. The measured is 2.809 ± 0.037 mas, while proper motions are 25.58 ± 0.04 mas yr⁻¹ in and 2.33 ± 0.04 mas yr⁻¹ in , refining earlier ground-based estimates from the UCAC4 catalog (23.1 ± 1.0 mas yr⁻¹ in RA and 3.7 ± 1.0 mas yr⁻¹ in Dec). These values indicate the star's membership in the population of the . The Transiting Exoplanet Survey Satellite (TESS) observed WASP-96 in 2-minute cadence mode during Sector 2 (August–September 2018, 27 days) and Sector 29 (August–September 2020, 24 days), providing high-precision photometry that revealed photometric modulations consistent with stellar rotation. These data enabled a measurement of the star's rotational period of 31.3₊₀.₃₋₃.₄ days and a low spot covering fraction of 1.35 ± 0.97%, indicating minimal chromospheric activity with no detectable Ca II H & K emission. No significant updates to stellar parameters or proper motions from additional surveys were reported through 2025.

Orbital characteristics

Orbital elements

WASP-96b orbits its host star at a semi-major axis of 0.0453 ± 0.0013 , placing it in a close-in configuration typical of hot Sats and hot Jupiters. This distance was derived using Kepler's third law, incorporating the and the host star's mass from spectroscopic analysis. The planet's orbit is nearly circular, with an eccentricity fixed at e = 0 in the primary analysis, consistent with (RV) measurements that show no evidence of eccentricity and upper limits of e < 0.27 at 3σ confidence. Subsequent refinements confirm this low eccentricity, with e < 0.11. The circular nature simplifies the orbital dynamics and aligns with the lack of tidal dissipation signatures expected for such short-period systems. The host star's mass contributes to the orbital stability by determining the gravitational potential well that maintains this configuration over billions of years. The orbital inclination is 85.45° ± 0.20°, nearly edge-on as inferred from the transit geometry observed in photometry. This value was obtained through modeling of the transit light curve, which provides constraints on the impact parameter and thus the inclination. A comprehensive orbital solution for was achieved by jointly fitting transit photometry from WASP-South, , and EulerCAM with RV data from Euler/CORALIE, yielding consistent parameters without the need for eccentricity in the model. Given the adopted circular orbit, the longitude of periastron is undefined and not constrained by the data. Refinements from TESS observations confirm the stability of these parameters.

Transit parameters

The transits of across its host star are characterized by a total duration from first to fourth contact of 2.462 ± 0.027 hours. This duration was derived from TESS photometry, which captured the ingress and egress phases effectively due to the planet's relatively central passage. The transit depth, measured as the fractional decrease in stellar flux, is 0.0138 ± 0.0003 (or 1.38 ± 0.03%), corresponding to the squared ratio of the planetary to stellar radius. This value was obtained from the initial light curves analyzed in the discovery observations, providing a benchmark for subsequent refinements. More recent analyses, including those from TESS data, report a slightly higher depth of 1.422 ± 0.013%, consistent within uncertainties and highlighting the stability of the photometric signal. The impact parameter bb, which quantifies the projected alignment of the planet's orbit relative to the stellar disk, is 0.724^{+0.019}_{-0.020} for . This near-central transit ( b<1b < 1 ) minimizes geometric distortions and facilitates precise measurements of the light curve shape. Updated fits from space-based observations yield similar values, confirming the robustness of the geometric model. Limb darkening effects, arising from the stellar atmosphere's temperature gradient, were accounted for in the analysis of the original WASP survey light curves using four-parameter non-linear laws with coefficients a1=0.722a_1 = 0.722, a2=0.581a_2 = -0.581, a3=1.203a_3 = 1.203, and a4=0.561a_4 = -0.561, based on Claret tables for the relevant filters and stellar parameters. These corrections are essential for accurate depth and duration estimates, as the planet's path grazes the stellar limb minimally but still samples the darkening profile. Given the orbital period of 3.425 days, transits recur frequently, occurring approximately every 3.425 days, which has enabled multiple observations across ground- and space-based facilities. No significant transit timing variations have been detected in this single-planet system, with ephemerides remaining stable and consistent with a constant period.

Physical characteristics

Mass and radius

WASP-96b has a mass of 0.48±0.030.48 \pm 0.03 Jupiter masses, determined from radial velocity measurements yielding a semi-amplitude K=62±4K = 62 \pm 4 m/s. These radial velocities were obtained using the CORALIE spectrograph on the Euler 1.2-m telescope, with the mass derived through modeling the planetary gravitational influence on the host star. The planet's radius measures 1.20±0.061.20 \pm 0.06 Jupiter radii, inferred from the transit depth in photometric observations combined with the host star's radius of 1.05±0.051.05 \pm 0.05 solar radii. Transit light curves were captured using the WASP-South array, EulerCAM on the Euler telescope, and the TRAPPIST telescope, with limb-darkening coefficients adopted from stellar atmosphere models. Both mass and radius parameters were refined via a combined Markov-chain Monte Carlo (MCMC) fitting process that simultaneously analyzed the radial velocity data and multiple transit light curves, assuming a circular orbit consistent with the measurements (eccentricity upper limit of 0.27 at 3σ confidence). This approach accounts for uncertainties in stellar parameters and instrumental noise, yielding robust estimates for the planet's physical size. Due to its close orbit receiving intense stellar irradiation, WASP-96b maintains an equilibrium temperature of approximately 1285 ± 40 K, calculated assuming zero and efficient heat redistribution. These properties classify WASP-96b as a hot Saturn-mass exoplanet, with its inflated radius indicative of thermal expansion from the high insolation.

Density and internal structure

The bulk density of WASP-96b, derived from its measured mass of 0.48 ± 0.03 Jupiter masses and radius of 1.20 ± 0.06 Jupiter radii, is approximately 0.37 ± 0.05 g/cm³. This value is notably lower than that of solar system gas giants like Jupiter (1.33 g/cm³) or Saturn (0.69 g/cm³), signifying a highly inflated structure dominated by an extended envelope. The low density reflects the planet's classification as a puffed-up hot Saturn, where intense stellar irradiation maintains elevated internal temperatures, expanding the gaseous layers. The planet's inflated radius, exceeding expectations for its mass under isolated conditions, is explained by additional energy input beyond stellar insolation. Proposed mechanisms include ohmic dissipation, where magnetic fields and zonal winds in the envelope generate resistive heating deep within the interior, and tidal heating from orbital eccentricity or star-planet interactions, which deposits energy via dynamical tides. The low density suggests a structure with a small core and a predominantly hydrogen-helium envelope.

Atmosphere

Spectroscopic analysis

The spectroscopic analysis of WASP-96b's atmosphere primarily relies on transmission spectroscopy, which exploits the planet's transit across its host star to measure how starlight is filtered through the planetary atmosphere at different wavelengths. This technique reveals spectral features by comparing the planet's apparent size during transit to broadband photometry. Ground-based observations began with optical transmission spectroscopy using the FOcal Reducer and low dispersion Spectrograph 2 (FORS2) on the Very Large Telescope (VLT) in 2018, targeting the sodium resonance doublet around 589 nm. These observations achieved a resolution of R ≈ 2000 over a wavelength range of 0.4–0.85 μm, enabling the detection of broad absorption features indicative of a cloud-free atmosphere. Follow-up ground-based efforts, such as those with the Inamori-Magellan Areal Camera and Spectrograph (IMACS) on the Magellan Clay 6.5 m telescope at Las Campanas Observatory, confirmed these findings in the 475–825 nm range using similar low-to-medium resolution spectroscopy. Space-based spectroscopy advanced significantly with the James Webb Space Telescope (JWST), starting with Early Release Observations in 2022 using the Near-Infrared Imager and Slitless Spectrograph (NIRISS) in Single Object Slitless Spectroscopy (SOSS) mode. This provided high signal-to-noise ratio (SNR > 100 per pixel) transmission spectra covering 0.8–2.8 μm at a resolving power of R ≈ 300–700, capturing fine atmospheric details. Key analytical techniques include spectral retrieval modeling, such as Bayesian frameworks like TauREx or , which fit observed spectra to forward models of atmospheric transmission to infer properties like temperature-pressure profiles and opacity sources. methods are employed in to align and stack spectral traces, enhancing stability and reducing systematics in time-series observations, particularly for JWST's slitless modes. These approaches, combined with wavelength coverage from 0.8–5 μm, facilitate robust probing of molecular absorption bands in the .

Composition and features

The atmosphere of WASP-96b contains (H₂O), detected at high confidence levels through transmission spectroscopy observations conducted by the (JWST) in 2022 using the Near-Infrared Imager and Slitless Spectrograph (NIRISS) instrument. Retrieval analyses from these data indicate a water mixing ratio of approximately 10310^{-3}, corresponding to log10(H2O)=3.590.35+0.35\log_{10}(\mathrm{H_2O}) = -3.59^{+0.35}_{-0.35}. Observations also reveal evidence for clouds or haze in the atmosphere, manifested as an enhanced slope in the near-infrared spectrum, with a scattering exponent γ=4.001.01+0.76\gamma = -4.00^{+0.76}_{-1.01}. This feature suggests the presence of small particles causing wavelength-dependent opacity, and retrievals favor inhomogeneous cloud distributions at a 6σ significance over a uniform grey cloud deck. Additionally, there is tentative evidence for sodium absorption, with a volume mixing ratio log10(Na)=6.853.10+2.48\log_{10}(\mathrm{Na}) = -6.85^{+2.48}_{-3.10} detected at 1.24σ . Retrieval models show no strong detections of (CH₄) or (CO), with unconstrained abundances for CH₄ (log10(CH4)=8.862.05+2.07\log_{10}(\mathrm{CH_4}) = -8.86^{+2.07}_{-2.05}) and an upper limit for CO (log10(CO)=3.255.06+0.91\log_{10}(\mathrm{CO}) = -3.25^{+0.91}_{-5.06}, 1.72σ). These results, combined with the prominent signal and detection of CO₂ (log10(CO2)=4.380.57+0.47\log_{10}(\mathrm{CO_2}) = -4.38^{+0.47}_{-0.57}), point to an oxygen-rich chemistry in the atmosphere, consistent with a carbon-to-oxygen ratio near solar values (log10(C/O)=0.300.37+0.17\log_{10}(\mathrm{C/O}) = -0.30^{+0.17}_{-0.37}). Temperature-pressure profiles derived from the retrievals indicate a clear upper atmosphere with an isothermal structure at approximately 944 K, extending over pressures from 10710^{-7} to 100 bar.

Scientific significance

Role in exoplanet research

WASP-96b played a pivotal role in research as the subject of the James Webb Space Telescope's (JWST) first clear detection of in the atmosphere of a hot . In July 2022, JWST's Near-Infrared Imager and Slitless Spectrograph (NIRISS) captured a transmission spectrum of the planet during transit, revealing distinct absorption features from molecules at wavelengths around 1.4 and 1.8 micrometers, marking the clearest of H₂O to date in such an environment. This observation, part of JWST's Early Release Science program, surpassed previous ground- and space-based detections by resolving subtle signals that hinted at but lacked definitive confirmation. The planet's suitability as a benchmark for transmission spectroscopy stems from its host star's brightness and the cloud-free nature of its upper atmosphere, which minimize noise and scattering effects that obscure signals in other targets. WASP-96, a dwarf with an apparent magnitude of 12.2, provides ample flux for high-precision measurements, while the planet's hazy but transparent layers allow direct probing of molecular abundances without heavy cloud interference. This combination enabled JWST to achieve a signal-to-noise ratio sufficient for detecting not only but also hints of and clouds, setting a standard for future atmospheric characterizations of hot Jupiters and Saturns. As an early science target, WASP-96b's validated JWST's performance in studies, demonstrating the telescope's sensitivity to faint atmospheric signals and informing subsequent mission planning and instrument calibration. The data confirmed expectations for NIRISS's single-object slitless mode, influencing the selection of over 100 programs in JWST's first year by proving the feasibility of routine transmission spectroscopy for distant worlds. Recent analyses in 2025, reprocessing the 2022 NIRISS data with advanced retrieval techniques, have confirmed the persistence of these spectral features, with no major deviations in absorption or overall structure, though they provide broader constraints on trace gases like CO₂. These refinements, using models to address systematics, reinforce WASP-96b's status as a stable reference for testing atmospheric retrieval algorithms.

Comparisons and implications

WASP-96b shares characteristics with other hot Saturn exoplanets, such as , both featuring low densities and inflated radii due to intense stellar irradiation, but its transmission spectrum reveals clearer molecular features owing to a lower atmospheric of approximately solar levels compared to the super-solar enrichment (3–10 times solar) observed in . This reduced in WASP-96b results in less pronounced opacity, enabling sharper detection of absorption lines from species like and metals, in contrast to the more obscured spectra of higher- counterparts. The planet's short of 3.4 days and proximity to its host star (0.045 AU) imply significant inward migration from cooler formation zones beyond the protoplanetary disk's , consistent with disk-driven migration models for hot Saturns that preserve low-density envelopes while avoiding excessive mass loss. This migration history aligns with core accretion formation scenarios, where WASP-96b's solar supports accretion from gas-dominated regions without substantial pollution, offering constraints on the efficiency of migration mechanisms in producing the observed of hot Saturns. As a highly irradiated with an equilibrium temperature around 1300 K, WASP-96b provides insights into processes, where hydrodynamic outflow driven by stellar XUV radiation may erode its extended hydrogen-helium envelope, potentially contributing to its inflated radius and low density. Observations of haze, indicated by in its near-infrared spectrum, highlight non-uniform aerosol formation in such environments, with photochemical hazes forming on the dayside and clouds condensing deeper in the atmosphere, influencing the planet's radiative balance and observability. Future multi-wavelength observations, including phase curves across ultraviolet to mid-infrared bands, hold promise for mapping WASP-96b's three-dimensional atmospheric structure, revealing day-night circulation patterns and cloud distributions that refine models of haze transport and escape in irradiated giants. Such studies could distinguish between uniform and inhomogeneous haze scenarios, enhancing understanding of atmospheric dynamics in this class.
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