WASP Planets

Transiting exoplanets from the Wide Angle Search for Planets

Skip to content
  • Home
  • About
  • Naming
  • Status
  • WASP Planets
  • Story of WASP
  • Papers
  • Technical
    • Images

Comparing refractory to volatile elements in ultra-hot Jupiter WASP-121b

Here’s a thread by Joshua Lothringer (@JDLothringer) who researches exoplanet atmospheres at Johns Hopkins University. It’s based on his new paper on arXiv:








Related

This entry was posted in exoplanet atmospheres, Exoplanet formation, exoplanets, Hot Jupiters, WASP planets and tagged Ultra-hot Jupiters, WASP-121b on December 4, 2020 by waspplanets.

Post navigation

← A second planet for WASP-107 Confirmation of the changing orbital period of WASP-12b →

Recent Posts

  • MPIA press release: An exotic water cycle and metal clouds on the hot Jupiter WASP-121 b
  • NASA press release: Hubble probes extreme weather on ultra-hot Jupiters
  • WASP-132c: A rocky companion to hot-Jupiter WASP-132b
  • CHEOPS observes WASP-189b
  • Tidal deformation of WASP-103b
  • Hot Jupiters often have polar orbits
  • Aerosol particles make WASP-69b’s atmosphere hazy
  • CHEOPS observations of WASP transits

WASP planet papers

Search ADS for latest WASP papers

Enter your email address to follow this blog and receive notifications of new posts by email.

Contact

waspplanets@gmail.com
Twitter: @WASPplanets

Categories

  • exoplanet atmospheres
  • Exoplanet formation
  • exoplanets
  • HATnet planets
  • Hot Jupiters
  • Hot Neptunes
  • Hubble Space Telescope
  • James Webb Space Telescope
  • K2 planets
  • KELT planets
  • Kepler planets
  • Solar System
  • TESS
  • Uncategorized
  • WASP planets
  • WASP project

Tags

  • albedo
  • aluminium oxide
  • Amaury Triaud
  • brown dwarfs
  • Cheops
  • clouds
  • companion planets
  • Coralie
  • ESPRESSO
  • Euler
  • exomoons
  • exoplanet discovery
  • exoplanet names
  • exoplanets
  • exoplanet transits
  • gravity darkening
  • helium
  • Hot Jupiter
  • Hubble Space Telescope
  • IAU
  • irradiation
  • JWST
  • K2
  • Keck
  • Kepler
  • Laura Kreidberg
  • magnetic activity
  • MASCARA
  • metallicity
  • Michel Mayor
  • NASA
  • occultation
  • orbital decay
  • orbital obliquity
  • orbital period decay
  • period change
  • phase curve
  • planet formation
  • RAS
  • Rossiter-McLaughlin effect
  • Sodium
  • Spitzer
  • Spitzer Space Telescope
  • starspots
  • stratosphere
  • super-Earths
  • Telescopio Nazionale Galileo
  • tidal damping
  • tidal decay
  • tidal interaction
  • transit
  • transit depth
  • transits
  • transit times
  • transit timing
  • transmission spectroscopy
  • TRAPPIST
  • TTVs
  • Ultra-hot Jupiters
  • Vivien Parmentier
  • VLT
  • WASP-4b
  • WASP-6b
  • WASP-8b
  • WASP-10
  • WASP-10b
  • WASP-12b
  • WASP-17b
  • WASP-18
  • WASP-18b
  • WASP-19b
  • WASP-22
  • WASP-31b
  • WASP-33b
  • WASP-36b
  • WASP-39b
  • WASP-43b
  • WASP-47
  • WASP-53
  • WASP-62b
  • WASP-67b
  • WASP-69b
  • WASP-76b
  • WASP-79b
  • WASP-85
  • WASP-100b
  • WASP-103b
  • WASP-104b
  • WASP-107b
  • WASP-121b
  • WASP-126b
  • WASP-127b
  • WASP-148
  • WASP-148b
  • WASP-148c
  • WASP-166b
  • WASP-189
  • WASP-189b
  • WASP-South
  • water

Archives

Blogroll

  • CHEOPS
  • EChO
  • Exoplanet.eu
  • Exoplanets.org
  • Kepler
  • NGTS
  • SWEET-Cat
  • TEPCat
  • TESS
  • Twinkle

Archive

WASP archive @NASA
Blog at WordPress.com.
  • Follow Following
    • WASP Planets
      • Join 72 other followers
    • Already have a WordPress.com account? Log in now.
    • WASP Planets
    • Customize
    • Follow Following
    • Sign up
    • Log in
    • Copy shortlink
    • Report this content
    • View post in Reader
    • Manage subscriptions
    • Collapse this bar
 

Loading Comments...