Nicole Wallack (Caltech)

Slides:

Advertisements

Similar presentations

THESIS – the Terrestrial and Habitable-zone Exoplanet Spectroscopy Infrared Spacecraft a concept for a joint NASA/ESA exoplanet characterization mission.

Advertisements

Jonathan Fortney University of California, Santa Cruz Spectroscopy of Giant Planets JWST Transit Planets Meeting PPVI Review: Madhusudhan, Knutson, Fortney,

Ge/Ay133 What can transit observations tell us about (exo)-planetary science? Part II – “Spectroscopy” & Atmospheric Composition/Dynamics Kudos to Heather.

Opacities and Chemical Equilibria for Brown Dwarf and Extra-Solar Giant Planet Models Christopher M. Sharp June 9, 2004.

Molecular Opacities and Collisional Processes for IR/Sub-mm Brown Dwarf and Extrasolar Planet Modeling Phillip C. Stancil Department of Physics and Astronomy.

Signatures of Exoplanets HD209458b: a Hot Jupiter Orbiting a Bright Star Sara Seager Carnegie Institution of Washington Image credit: NASA/JPL-Caltech/R.

Exploring a Nearby Habitable World …. Orbiting an M-dwarf star Drake Deming NASA’s Goddard Space Flight Center.

1 A Carbon Rich Mira Variable In a Globular Cluster: A Stellar Merger MW Feast JW Menzies PA Whitelock SAAO and UCT Published online MNRAS Letters 29 Oct.

Dynamics of Hot Jupiter Atmospheres Adam P. Showman University of Arizona.

Some of the Hot Jupiters do not match well models based on Jupiter & Saturn: Gas Giant Planets. III. Gaudi (2005) & Charbonneau et al (2006) w Bodenheimer.

Modeling Carbon Species in the Atmosphere of Neptune and Comparison with Spitzer Observations Xi Zhang 1, Mao-Chang Liang 2, Daniel Feldman 1, Julianne.

PX437 EXOPLANETS Outline 1.Before Exoplanets 2.Detecting exoplanets 1.Direct imaging 2.Reflex Motion of Star 3.Transiting exoplanets 3.Planet Formation.

Mass Loss from Red Giant Branch (and AGB) Stars in Globular Clusters Andrea Dupree Harvard-Smithsonian Center for Astrophysics AGB Workshop: 20 May 2010.

Reflection Spectra of Giant Planets With an Eye Towards TPF (and EPIC & ECLIPSE) Jonathan J. Fortney Mark S. Marley NASA Ames Research Center 2005 Aspen.

Geophysics of Icy Saturnian Satellites Torrence V. Johnson Jet Propulsion Laboratory, Caltech.

Lecture V: Terrestrial Planets & Summary 1.Plate Tectonics 2.Atmospheres & Spectra 3.Geophysical Cycles 4.Future Exploration.

Ge/Ay133 What (exo)-planetary science can be done with transits and microlensing?

Extrasolar Planets.I. 1.What do we know and how do we know it. 2.Basic planetary atmospheres 3.Successful observations and future plans.

Formation of Stony-Iron Meteorites in Early Giant Impacts Pallasites were originally thought to.

Lecture III: Gas Giant Planets 1.From Lecture II: Phase separation 2.Albedos and temperatures 3.Observed transmission spectra 4.Observed thermal spectra.

New Results from Ground-Based Transit Spectroscopy Observations Jacob Bean Harvard-Smithsonian CfA University of Chicago.

Lecture 16: Searching for Habitable Planets: Remote Sensing Methods and parameters we can measure Mean density measurements: internal structure Measurements.

Orbital motion, absolute mass & high-altitude winds of HD b Ignas Snellen, Remco de Kok, Ernst de Mooij, Simon Albrecht Nature – May 2010.

Lecture 34. Extrasolar Planets. reading: Chapter 9.

SPICA Science for Transiting Planetary Systems Norio Narita Takuya Yamashita National Astronomical Observatory of Japan 12009/06/02 SPICA Science Workshop.

The Grand Tour of Exoplanets The New Worlds around Other Stars The Grand Tour of Exoplanets The New Worlds around Other Stars Dániel Apai Space Telescope.

Venus: Earth’s Twin?.

Transits of exoplanets – Detection & Characeterization

1 An emerging field: Molecules in Extrasolar Planets Jean Schneider - Paris Observatory ● Concepts and Methods ● First results ● Future perspectives.

Investigating the structure of transiting planets, from hot Jupiters to Kepler super Earths Jonathan Fortney University of California, Santa Cruz Thanks.

National Aeronautics and Space Administration Mark Swain THESIS – the Terrestrial and Habitable-zone Exoplanet Spectroscopy Infrared Spacecraft characterizing.

Transit Spectroscopy w/ WFC3 March 11, 2014 Avi M. Mandell NASA GSFC Collaborators: Korey Haynes Evan Sinukoff Drake Deming Adam Burrows Nikku Madhusudhan.

Exoplanets: What’s new and next for HST? Jennifer Wiseman NASA GSFC.

Biosignatures: Alien’s View of Earth ASTR 1420 Lecture : 19 Section: Not from the textbook.

Exoplanet Transit Spectroscopy February 7, 2014 Avi M. Mandell NASA GSFC Collaborators: Korey Haynes Evan Sinukoff Drake Deming Adam Burrows Nikku Madhusudhan.

A Warm Spitzer Survey of Atmospheric Circulation Patterns Image credit G. Orton Heather Knutson (Caltech) In collaboration with: N. Lewis (Arizona), N.

Lecture 14: The Discovery of the World of Exoplanets Indirect methods for planet detection The Astrometric method The Doppler shift method The Transit.

1 Neptune Mass Exoplanets Jeff Valenti M Jupiter / 19 = M Neptune = 17 M Earth Geoff Marcy (Berkeley)Debra Fischer (Yale) Andrew Howard (Berkeley)John.

Transit Spectroscopy with HST/WFC3 January 18, 2012 Exoplanet Transit Spectroscopy with HST/WFC3: Probing H 2 O with New Precision Avi M. Mandell NASA.

Young Jupiters are Faint Jonathan Fortney (NASA Ames) Mark Marley (Ames), Olenka Hubickyj (Ames/UCSC), Peter Bodenheimer (UCSC), Didier Saumon (LANL) Don.

Retrievals of Dayside Emission Spectra: Trends in Chemistry Michael Line, Aaron Wolf, Xi Zhang, Yuk Yung Caltech.

IGRINS Science Workshop High Spectral Resolution Mid- Infrared Spectroscopy as a Probe of the Physical State of Planetary Atmospheres August 26,

Characterizing atmospheres with JWST: Optimizing multi-instrument observations via simulations and retrievals Tom Greene (NASA ARC) Michael Line (UCSC.

Exoplanet Characterization with JWST

Reflected Light: Albedo Measurements Radiated Light: Temperature In-transit and secondary eclipse spectroscopy: Atmospheric Features Characterization of.

How Other Projects Will Enable JWST Transiting Planet Science David Charbonneau (Harvard) 18 November 2015.

The Study of Exoplanetary Atmosphere with IGRINS Keun-Hong Park Seoul National University.

JWST Spectroscopy of transiting planets Drake Deming University of Maryland at College Park K2 Science Conference, November 5, 2015.

Greenhouse Effect Sun Earth’s Temperature Solar Energy Solar Energy Solar Energy Solar Energy.

Luminosity and Spectra of Young Jupiters Jonathan J. Fortney University of California, Santa Cruz Mark Marley (NASA Ames) Olenka Hubickyj (NASA Ames) Peter.

Characterisation of hot Jupiters by secondary transits observed with IRIS2 Lucyna Kedziora-Chudczer (UNSW) George Zhou (Harvard-Smithsonian CfA) Jeremy.

Planets Orbiting M Stars

user perspective Status Report on SOFIA Exoplanet Transit Capability

Exoplanet Characterization ToolKit (ExoCTK)

BATMAN & SPIDERMAN: Saving the World One Exoplanet Light Curve at a Time talk about two open-source Python package for modeling transits, eclipses, and.

Nature of Exoplanets 26 October 2016.

Microwave/Submillimeter Astronomy

Determining Abundances

Ravit Helled Institute for Computational Science

Savage et al. Copper isotope evidence for large-scale sulphide fractionation during Earth’s differentiation Figure 2 Schematic evolution of Cu concentration.

Karl Haisch Jr. (Utah Valley University)

Exoplanet Host Stars.

Past and Future Studies of Transiting Extrasolar Planets

Clouds Near Quasars Redefined

Very Cool Brown Dwarfs and Subdwarfs Identified at IRTF

SPICA for Transiting Exoplanets: Which SPICA instruments are useful?

UVIS Saturn EUVFUV Data Analysis

Direct imaging discovery of a Jovian exoplanet within a triple-star system by Kevin Wagner, Dániel Apai, Markus Kasper, Kaitlin Kratter, Melissa McClure,

Outer Planets A.K.A. Gas Giants.

Presentation transcript:

Nicole Wallack (Caltech) Investigating Trends in Atmospheric Compositions of Cool Gas Giant Planets Using Spitzer Secondary Eclipses Nicole Wallack (Caltech) Heather Knutson, Caroline Morley, Nancy Thomas, Daniel Thorngren, Jean-Michel Désert, Jonathan Fortney, Joshua Kammer, and Julianne Moses

Using Solar System Trends to Probe Planet Evolution Increasing atmospheric “metallicity” C/H ~ 4 x Solar metallicity C/H ~ 70 x Solar metallicity (Wong et al. 2004) (Karkoschka & Tomasko 2011; Sromovsky et al. 2011) NASA Decreasing core mass fraction/ Increasing mass

Clouds Affect Our Ability to Detect an Atmospheric Composition-Planet Mass Trend from Transmission Spectra (Adapted from Wakeford et al. 2018) (Figure from Parmentier et al. 2016)

Using Spitzer Secondary Eclipses to Determine Atmospheric Composition WASP-69b Downward Slope High CO/CH4 absorption Upward Slope Low CO/CH4 Absorption (Moses et al. 2013; Stevenson et al. 2012; Morley et al. 2016)

Secondary Eclipses of Cool (T< ~1000 K) Planets 8 Previously Published Planets 2 Planets In-Prep: GJ 3470b HAT-P-12b 5 New Planets: HAT-P-15b HAT-P-17b HAT-P-26b HAT-P-18b WASP-69b 1.9MJ 0.2 MJ 0.5 MJ 0.06 MJ 0.3 MJ 900 K 800 K 800 K 1000 K 1000 K Multiple Visits in Each Spitzer Bandpass

No Trend in Atmospheric Composition With Temperature CH4 Rich CO Poor Sanity check: 0.8- 26.3 x solar (Wakeford et al. 2017) HAT-P-26b GJ 3470b Sanity check: > 200 x solar (Moses et al. 2013; Morley et al. 2016) CO Rich CH4 Poor GJ 436b (Wallack et al. in prep)

No Trend in Atmospheric Composition With Planet Mass CH4 Rich CO Poor HAT-P-26b GJ 3470b CO Rich CH4 Poor GJ 436b (Wallack et al. in prep)

Possible Trend in Atmospheric Composition With Bulk Metallicity CH4 Rich CO Poor HAT-P-26b GJ 3470b CO Rich CH4 Poor GJ 436b (Wallack et al. in prep) Thorngren et al. 2016

Evidence for a Trend in Atmospheric Composition With Stellar Metallicity CH4 Rich CO Poor HAT-P-26b GJ 3470b CO Rich CH4 Poor GJ 436b (Wallack et al. in prep)

JWST Will Allow Us to Better Constrain Atmospheric Compositions NASA