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UV absorption by silicate cloud precursors in ultra-hot Jupiter WASP-178b

Nature volume 604pages 49–52 (2022)Cite this article

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Abstract

Aerosols have been found to be nearly ubiquitous in substellar atmospheres1,2,3. The precise temperature at which these aerosols begin to form in exoplanets has yet to be observationally constrained. Theoretical models and observations of muted spectral features indicate that silicate clouds play an important role in exoplanets between at least 950 and 2,100 K (ref. 4). Some giant planets, however, are thought to be hot enough to avoid condensation altogether5,6. Here we report the near-ultraviolet transmission spectrum of the ultra-hot Jupiter WASP-178b (approximately 2,450 K), which exhibits substantial absorption. Bayesian retrievals indicate the presence of gaseous refractory species containing silicon and magnesium, which are the precursors to condensate clouds at lower temperatures. SiO, in particular, has not previously, to our knowledge, been detected in exoplanets, but the presence of SiO in WASP-178b is consistent with theoretical expectations as the dominant Si-bearing species at high temperatures. These observations allow us to re-interpret previous observations of HAT-P-41b and WASP-121b that did not consider SiO, to suggest that silicate cloud formation begins on exoplanets with equilibrium temperatures between 1,950 and 2,450 K.

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Fig. 1: WASP-178b NUV-optical transmission spectrum.
Fig. 2: Comparison of NUV-optical transmission spectra.
Fig. 3: Atmospheric structures and condensation curves.

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Data availability

The raw data from this study, HST Program 16068, is publicly available via the Space Science Telescope Institute’s Mikulski Archive for Space Telescopes (https://archive.stsci.edu/).

Code availability

The raw data was reduced with the available STScI CALWF3 pipeline and spectra were extracted with the public IRAF apall routines. The light curve fitting used custom routines that we opt not to make public due to undocumented intricacies. Model and retrievals were generated using PHOENIX, which is a proprietary code but described in many publications, for example, refs. 66,67.

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Acknowledgements

We thank the UV-SCOPE team for relevant discussions. We thank T. Barman for the use of the computing resources used in the calculation of the atmospheric retrievals. Support for this work was provided by NASA through grant number HST-GO-16086 from the Space Telescope Science Institute, which is operated by AURA, Inc., under NASA contract NAS 5-26555. This research has made use of the NASA Astrophysics Data System and the NASA Exoplanet Archive, which is operated by the California Institute of Technology, under contract with the National Aeronautics and Space Administration under the Exoplanet Exploration Program.

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Author notes

  1. These authors contributed equally: Joshua D. Lothringer, David K. Sing

Authors and Affiliations

  1. Department of Physics, Utah Valley University, Orem, UT, USA

    Joshua D. Lothringer

  2. Department of Physics and Astronomy, Johns Hopkins University, Baltimore, MD, USA

    Joshua D. Lothringer & David K. Sing

  3. Department of Earth & Planetary Sciences, Johns Hopkins University, Baltimore, MD, USA

    David K. Sing, Zafar Rustamkulov & Kevin B. Stevenson

  4. School of Physics, University of Bristol, HH Wills Physics Laboratory, Bristol, UK

    Hannah R. Wakeford

  5. Applied Physics Laboratory, Johns Hopkins University, Laurel, MD, USA

    Kevin B. Stevenson

  6. Space Telescope Science Institute, Baltimore, MD, USA

    Nikolay Nikolov

  7. Groupe de Spectrométrie Moléculaire et Atmosphérique, Université de Reims, Champagne-Ardenne, CNRS UMR F-7331, Reims, France

    Panayotis Lavvas

  8. Department of Astronomy, California Institute of Technology, Pasadena, CA, USA

    Jessica J. Spake

  9. Department of Physics, Bryn Mawr College, Bryn Mawr, PA, USA

    Autumn T. Winch

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Contributions

J.D.L. and D.K.S. contributed equally to this work. J.D.L. led the observing proposal with the assistance of D.K.S., Z.R., H.R.W., K.B.S., N.N. and P.L. J.D.L. also led the retrieval analysis. D.K.S. led the data analysis with contributions from Z.R., H.R.W., J.J.S. and A.T.W. All authors discussed the data analysis and interpretation and commented on the manuscript.

Corresponding authors

Correspondence to Joshua D. Lothringer or David K. Sing.

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Extended data figures and tables

Extended Data Fig. 1 White light curves of the WASP-178b HST/WFC3/UVISG280 transit.

Error bars show the 1-σ uncertainties. The left column (a, c, e) shows the +1 spectral order, while the right column (b, d, f) shows the −1 spectral order. The top row (a, b) are the raw light curves, the middle row (c, d) are the light curves with systematics removed and a transit fit, and the bottom row (e, f) are the residuals with the standard deviation of the residuals also shown (dotted lines). Plots of the binned residual RMS are also shown as insets.

Extended Data Fig. 2 WASP-178b NUV-optical light curve comparison.

Two example fitted light curves with 1-σ uncertainties from the +1 spectral order from spectroscopic bins covering 0.2412 (a, c, e) and 0.5875 μm (b, d, f), with transit depths of 1.48 ± 0.04% and 1.16 ± 0.03%, respectively. The rows are the same as in Extended Data Fig. 1.

Extended Data Fig. 3 WASP-178b spectral order comparison.

WFC3/UVIS G280 transmission spectrum of WASP-178b (with 1-σ uncertainties) from the +1 (blue) and −1 order (red). The −1 order shows larger uncertainties due to a reduced throughput, but the transmission spectra show good agreement including an enhanced NUV absorption between 0.2 and 0.3 µm.

Extended Data Fig. 4 WASP-178b transit asymmetry analysis.

a, The 0.18–0.28 µm NUV light curve of WASP-178 b (with 1-σ uncertainties), with the best-fitting symmetric light curve, and an asymmetric light curve representing a scenario with a hotter/larger trailing terminator, and a colder/smaller leading terminator. The radius of the leading terminator was set to the optical value, and the trailing terminator was fixed to the value that fits the NUV transit depth. The inset shows the RMS scatter of the residuals as a function of number of points per bin, N. b, Residuals to the symmetric and asymmetric light curve fits.

Extended Data Fig. 5 WASP-178b atmospheric retrieval posterior distribution.

2-D cross- sections of the retrieved posterior distribution with 1-D marginalized distribution for the fitted parameters. The quoted quantities are the mean and 1-σ retrieved values. The first five parameters are the temperature structure parameterization from ref. 57, the sixth is the reference radius, and the final eight are the various atomic and molecular abundances.

Extended Data Fig. 6 WASP-178b NUV-optical transmission spectrum (no SiO).

Same as Fig. 1, but for the retrieval without SiO. Note the combined ability of Mg I and Fe II absorption to generate the large short-wavelength transit depths.

Extended Data Fig. 7 Chemical equilibrium of Si and Fe.

Partial pressures of important silicon- bearing species (a) and iron-bearing species (b) at 1 mbar as a function of temperature. Equilibrium chemical abundances were calculated using GGchem69.

Extended Data Fig. 8 High-resolution HST/STIS/E230M transmission spectrum of WASP- 178b.

NUV high-resolution transit spectra of WASP-178b (with 1-σ uncertainties) compared to WASP-121b around the Fe II (a) and Mg II (b) lines. Shown are the spectra from STIS E230M for WASP-178b (red), WASP-121b17 (grey), and the low resolution UVIS spectra (blue). While WASP-121b shows strong Fe II and Mg II absorption features, the WASP-178b E230M spectra is consistent with the broadband NUV continuum with no Fe II or Mg II.

Extended Data Table 1 WASP-178 HST/WFC3/UVIS transmission spectrum and noise properties
Full size table
Extended Data Table 2 WASP-178b fitted and retrieved orbital and atmosphere parameters
Full size table

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Lothringer, J.D., Sing, D.K., Rustamkulov, Z. et al. UV absorption by silicate cloud precursors in ultra-hot Jupiter WASP-178b. Nature 604, 49–52 (2022). https://doi.org/10.1038/s41586-022-04453-2

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