WASP-193b#Host star

The planet was discovered in July 2023 by a team of astronomers led by Khalid Barkaoui, a researcher at the University of Liège, from observational data taken by WASP (Wide Angle Search for Planets) in 2006–2008 and 2011–2012. It is one of hundreds discovered in the WASP mission, which uses transit photometry to find exoplanets, observing the dimming of a star caused by the astronomical transit of planets passing in front of them.

The discovery was subsequently confirmed photometrically by TRAPPIST-South, SPECULOOS-South, and the TESS mission, as well as through spectroscopic observations by HARPS and the CORALIE spectrograph of the Swiss 1.2-metre Leonhard Euler Telescope.

Due to WASP-193b's unusually low mass (and hence a weak gravitational pull) for a planet its size, initial observations failed to detect radial velocity signals in the spectra of WASP-193. Because of this, it took four years to gather sufficient data to determine the existence of a mass signal from the planet.

The planet orbits a yellow-white main-sequence star named WASP-193. The star has a mass of {{val|1.059|0.067|0.068}} {{Solar mass|link=y}}, a radius of {{val|1.239|0.028}} {{Solar radius|link=y}}, and a luminosity of {{val|1.87|0.18|0.16}} {{Solar luminosity|link=y}}. It has a surface temperature of {{convert|6078|K|C F}} and is {{val|4.4|1.9}} billion years old. In comparison, the Sun is 4.6 billion years old, has a temperature of {{convert|5772|K|C F}} and a spectral type of G2V. The apparent magnitude of the star is 12.134, making it too faint to be seen from Earth by the naked eye, but visible using a 60 mm aperture telescope.

The planet revolves around the star at a distance of just {{convert|0.0676|AU|km|abbr=on}}, over five times closer than Mercury is to the Sun (0.3871 AU). As a result, WASP-193b receives approximately 410 times more irradiance than the solar constant (i.e., the amount of energy received from the sun per given area at a distance of 1 AU), placing its equilibrium temperature at a smoldering {{convert|1254|K|C F|abbr=on}}, hot enough to melt silver.{{efn|Elemental silver melts at {{convert|961.78|C|K F}}.}} Due to its exposure to intense stellar radiation, the upper layers of the planet's atmosphere are being stripped away at a rate of 1.8{{e|10}} – 4.3{{e|11}} g per second, depending on the level of extreme ultraviolet flux.

WASP-193b has a radius of 1.464 {{Jupiter radius}} ({{val|104664|ul=km}}; 16.41 {{Earth radius|link=y}}), meaning the planet is approximately 3.1 times more voluminous than Jupiter.{{efn|Calculated from radius assuming a perfect non-oblate sphere, that is the cube of the planetary radius measured in Jupiter radii (1.464³≈3.138).}} Despite its enormous size, the planet only has a mass of 0.139 {{Jupiter mass}} (44.2 {{Earth mass|link=y}}; 2.58 times that of Neptune), making it a super-Neptune, which normally has less than half the radius (5-7 {{Earth radius}}). Thus, the density of the planet is estimated to be a mere {{val|0.059|ul=g/cm3}}—well below the typical value seen in gas giants ({{val|0.2|-|2|ul=g/cm3}}), and less than a tenth that of Saturn ({{val|0.687|ul=g/cm3}}), the least dense planet in the Solar System. As of May 2024, only one other planet, the super-puff planet Kepler-51d ({{val|0.046|0.009|ul=g/cm3}}), is known to have a lower density. Because of this, both planets are often likened to cotton candy (around {{val|0.05|ul=g/cm3}}) in media coverage.

Most of the planet's radius is thought to be taken up by a bloated atmosphere consisting of predominantly hydrogen and helium, but it remains unknown as to how such a large, light planet could exist, which classical models for gas giant evolution fail to explain. Assuming the planet's age to be 4.4 Gyr, a theoretical model published in 2007 regarding the radii of planets aged between 1.0 and 4.5 Gyr with a core mass of 0–10 {{Earth mass}} calculates its radius to be 0.9–1.1 {{Jupiter radius}}. Another model, published in 2013 and derived from the analysis of 35 exoplanets weighing less than 150 {{Earth radius}}, gives a value of {{val|0.82|0.14}} {{Jupiter radius}}. Calculations using a 2018 model based on data from 286 hot Jupiters with known masses and radii predicts the radius to be {{val|1.1|0.1}} {{Jupiter radius}}. All of these models fall well behind the measured value of 1.464 {{Jupiter radius}}, which, according to model calculations, can only be sustained for a few tens of millions of years, far shorter than the age of the host star, hinting at the presence of other previously unaccounted mechanisms at play.

Research into the anomalously light WASP-193b is said to become crucial for understanding the evolution of inflated planets that cannot be explained by ordinary theories for planetary evolution. Due to the large transit depth, extremely low density, and high equilibrium temperature of the planet, it is considered a prime target for transmission photometry observations by the James Webb Space Telescope.

• Other giant planets with similarly low densities:
• Kepler-51 b, c, d: three Jupiter-sized super-puff planets.
• WASP-17b, HAT-P-67b: puffy planets that are among the largest exoplanets despite having Saturn-like masses.

{{noteslist}}

{{Reflist|refs=

{{cite journal | last1=Barkaoui | first1=Khalid | last2=Pozuelos | first2=Francisco J. | last3=Hellier | first3=Coel | last4=Smalley | first4=Barry | last5=Nielsen | first5=Louise D. | last6=Niraula | first6=Prajwal | last7=Gillon | first7=Michaël | last8=de Wit | first8=Julien | last9=Müller | first9=Simon | last10=Dorn | first10=Caroline | last11=Helled | first11=Ravit | last12=Jehin | first12=Emmanuel | last13=Demory | first13=Brice-Olivier | last14=Van Grootel | first14=Valerie | last15=Soubkiou | first15=Abderahmane | last16=Ghachoui | first16=Mourad | last17=Anderson | first17=David. R. | last18=Benkhaldoun | first18=Zouhair | last19=Bouchy | first19=Francois | last20=Burdanov | first20=Artem | last21=Delrez | first21=Laetitia | last22=Ducrot | first22=Elsa | last23=Garcia | first23=Lionel | last24=Jabiri | first24=Abdelhadi | last25=Lendl | first25=Monika | last26=Maxted | first26=Pierre F. L. | last27=Murray | first27=Catriona A. | last28=Pedersen | first28=Peter Pihlmann | last29=Queloz | first29=Didier | last30=Sebastian | first30=Daniel | last31=Turner | first31=Oliver | last32=Udry | first32=Stephane | last33=Timmermans | first33=Mathilde | last34=Triaud | first34=Amaury H. M. J. | last35=West | first35=Richard G. | title=An extended low-density atmosphere around the Jupiter-sized planet WASP-193 b | journal=Nature Astronomy | volume=8 | issue=7 | date=2024-05-14 | issn=2397-3366 | doi=10.1038/s41550-024-02259-y | pages=909–919| arxiv=2307.08350 | bibcode=2024NatAs...8..909B |display-authors=1}}

{{cite web|author=Jean Schneider|url=https://exoplanet.eu/catalog/wasp_193_b--8756/|title=Planet WASP-193 b|website=The Extrasolar Planet Encyclopaedia|date=2024-01-27|accessdate=2024-05-19}}

{{cite simbad |title=WASP-193 |access-date=2024-08-02}}

{{cite web|author=Jennifer Chu|url=https://news.mit.edu/2024/astronomers-spot-giant-planet-light-as-cotton-candy-0514|title=Astronomers spot a giant planet that is as light as cotton candy|website=MIT News|publisher=MIT|date=2024-05-14|accessdate=2024-05-19}}

{{cite journal|last=Masuda|first=Kento|title=Very Low Density Planets around Kepler-51 Revealed with Transit Timing Variations and an Anomaly Similar to a Planet-Planet Eclipse Event|year=2014|journal=The Astrophysical Journal|volume=783|issue=1|pages=53|issn=0004-637X|doi=10.1088/0004-637X/783/1/53|bibcode=2014ApJ...783...53M|arxiv=1401.2885}}

{{cite web|url=https://edition.cnn.com/2024/05/16/world/cotton-candy-exoplanet-discovery-wasp-193b-scn/index.html|title=Unusual giant planet as fluffy as cotton candy spotted by astronomers|last=Asmelash|first=Leah|website=CNN|publisher=CNN|date=2024-05-16|access-date=2024-05-19}}

{{Cite journal |last1=Connelly |first1=JN |last2=Bizzarro |first2=M |last3=Krot |first3=AN |last4=Nordlund |first4=Å |last5=Wielandt |first5=D |last6=Ivanova |first6=MA |date=2 November 2012 |title=The Absolute Chronology and Thermal Processing of Solids in the Solar Protoplanetary Disk |journal=Science |volume=338 |issue=6107 |pages=651–655 |bibcode=2012Sci...338..651C |doi=10.1126/science.1226919 |pmid=23118187 |s2cid=21965292}}{{Registration required}}

{{Cite web |last=Williams |first=D.R. |title=Sun Fact Sheet |url=http://nssdc.gsfc.nasa.gov/planetary/factsheet/sunfact.html |url-status=live |archive-url=https://web.archive.org/web/20100715200549/http://nssdc.gsfc.nasa.gov/planetary/factsheet/sunfact.html |archive-date=2010-07-15 |access-date=2024-08-02 |publisher=NASA Goddard Space Flight Center}}

{{Cite web |last=Williams |first=D.R. |title=Mercury Fact Sheet |url=http://nssdc.gsfc.nasa.gov/planetary/factsheet/mercuryfact.html |access-date=2024-08-02 |publisher=NASA Goddard Space Flight Center}}

{{Cite web |last=Williams |first=D.R. |title=Saturn Fact Sheet |url=https://nssdc.gsfc.nasa.gov/planetary/factsheet/saturnfact.html |access-date=2024-08-02 |publisher=NASA Goddard Space Flight Center}}

{{cite web|date = February 2001|title = The Bortle Dark-Sky Scale|publisher = Sky & Telescope|author = John E. Bortle|url = http://www.skyandtelescope.com/resources/darksky/3304011.html|access-date = 2009-11-18|archive-url = https://web.archive.org/web/20090323232806/http://www.skyandtelescope.com/resources/darksky/3304011.html|archive-date = 2009-03-23|url-status = dead}}

{{cite book | title=Observing Variable Stars, Novae and Supernovae | first1=Gerald | last1=North | first2=Nick | last2=James | publisher=Cambridge University Press | date=2014 | isbn=978-1-107-63612-5 | page=24 | url=https://books.google.com/books?id=IzoDBAAAQBAJ&pg=PA24 }}

{{cite journal|last=Savanov|first=I. S.|title=Mass Loss from the Atmosphere of the Planet WASP-193 b|year=2024|journal=Astrophysics|volume=66|issue=4|pages=463–469|doi=

10.1007/s10511-024-09803-8|bibcode=2024Ap.....66..463S}}

{{cite web|title=Melting Point of Common Metals, Alloys, & Other Materials|url=https://www.americanelements.com/meltingpoint.html|access-date=2024-08-02}}

{{Cite web|url=http://www.space.com/6338-super-neptune-planet.html|title=Super-Neptune Planet Found|website=Space.com|date=14 March 2009}}

{{cite news|url=https://www.astronomy.com/science/second-lightest-exoplanet-known-surprises-astronomers/|title='This planet should not be there.' Second lightest exoplanet known to date surprises astronomers|website=astronomy.com|date=2024-05-28|access-date=2024-08-02}}

{{cite news|url=https://www.space.com/exoplanet-2nd-lightest-cotton-candy|title=Cotton candy exoplanet is 2nd lightest planet ever found|last=Lea|first=Robert|website=space.com|date=2024-05-16|access-date=2024-08-02}}

{{cite journal|last1=Fortney|first1=J. J.|last2=Marley|first2=M. S.|last3=Barnes|first3=J. W.|title=Planetary Radii across Five Orders of Magnitude in Mass and Stellar Insolation: Application to Transits|year=2007|journal=The Astrophysical Journal|volume=659|issue=2|pages=1661–1672|doi=10.1086/512120|bibcode=2007ApJ...659.1661F|arxiv=astro-ph/0612671}}

{{cite journal|last1=Weiss|first1=Lauren M.|last2=Marcy|first2=Geoffrey W.|last3=Rowe|first3=Jason F.|last4=Howard|first4=Andrew W.|display-authors=3|title=The Mass of KOI-94d and a Relation for Planet Radius, Mass, and Incident Flux|year=2013|journal=The Astrophysical Journal|volume=768|issue=1|id=14|page=19|doi=

10.1088/0004-637X/768/1/14|bibcode=2013ApJ...768...14W|arxiv=1303.2150}}

{{cite journal|last1=Sestovic|first1=M.|last2=Demory|first2=B.-O.|last3=Queloz|first3=D|title=Investigating hot-Jupiter inflated radii with hierarchical Bayesian modelling|year=2018|journal=Astronomy and Astrophysics|volume=616|issue=A76|page=13|doi=10.1051/0004-6361/201731454|bibcode=2018A&A...616A..76S|arxiv=1804.03075}}

}}

{{Hydra (constellation)}}

{{2023 in space}}

Category:Exoplanets discovered by WASP

Category:Giant planets

Category:Hot Neptunes

Category:Hot Jupiters

Category:Hydra (constellation)

Category:Exoplanets discovered in 2023

Category:Transiting exoplanets