Solar system

Analysis of Rosetta/VIRTIS spectra of earth using observations from ENVISAT/AATSR, TERRA/MODIS and ENVISAT/SCIAMACHY, and radiative-transfer simulations

Planetary and Space Science Elsevier BV 90 (2014) 37-59

Authors:

J Hurley, PGJ Irwin, A Adriani, M Moriconi, F Oliva, F Capaccioni, A Smith, G Filacchione, F Tosi, G Thomas

Atmospheric retrieval analysis of the directly imaged exoplanet HR 8799b

Astrophysical Journal 778:2 (2013)

Authors:

JM Lee, K Heng, PGJ Irwin

Abstract:

Directly imaged exoplanets are unexplored laboratories for the application of the spectral and temperature retrieval method, where the chemistry and composition of their atmospheres are inferred from inverse modeling of the available data. As a pilot study, we focus on the extrasolar gas giant HR 8799b, for which more than 50 data points are available. We upgrade our non-linear optimal estimation retrieval method to include a phenomenological model of clouds that requires the cloud optical depth and monodisperse particle size to be specified. Previous studies have focused on forward models with assumed values of the exoplanetary properties; there is no consensus on the best-fit values of the radius, mass, surface gravity, and effective temperature of HR 8799b. We show that cloud-free models produce reasonable fits to the data if the atmosphere is of super-solar metallicity and non-solar elemental abundances. Intermediate cloudy models with moderate values of the cloud optical depth and micron-sized particles provide an equally reasonable fit to the data and require a lower mean molecular weight. We report our best-fit values for the radius, mass, surface gravity, and effective temperature of HR 8799b. The mean molecular weight is about 3.8, while the carbon-to-oxygen ratio is about unity due to the prevalence of carbon monoxide. Our study emphasizes the need for robust claims about the nature of an exoplanetary atmosphere to be based on analyses involving both photometry and spectroscopy and inferred from beyond a few photometric data points, such as are typically reported for hot Jupiters. © 2013. The American Astronomical Society. All rights reserved..

WATER LOSS FROM TERRESTRIAL PLANETS WITH CO2-RICH ATMOSPHERES

The Astrophysical Journal American Astronomical Society 778:2 (2013) 154

Authors:

RD Wordsworth, RT Pierrehumbert

Colors of Jupiter's large anticyclones and the interaction of a Tropical Red Oval with the Great Red Spot in 2008

Journal of Geophysical Research Planets American Geophysical Union (AGU) 118:12 (2013) 2537-2557

Authors:

A Sánchez‐Lavega, J Legarreta, E García‐Melendo, R Hueso, S Pérez‐Hoyos, JM Gómez‐Forrellad, LN Fletcher, GS Orton, A Simon‐Miller, N Chanover, P Irwin, P Tanga, M Cecconi

Detection of propene in titan's stratosphere

Astrophysical Journal Letters 776:1 (2013)

Authors:

CA Nixon, DE Jennings, B Bézard, S Vinatier, NA Teanby, K Sung, TM Ansty, PGJ Irwin, N Gorius, V Cottini, A Coustenis, FM Flasar

Abstract:

The Voyager 1 flyby of Titan in 1980 gave a first glimpse of the chemical complexity of Titan's atmosphere, detecting many new molecules with the infrared interferometer spectrometer (IRIS). These included propane(C3H 8) and propyne (CH3C2H), while the intermediate-sized C3Hx hydrocarbon (C3H 6) was curiously absent. Using spectra from the Composite Infrared Spectrometer on Cassini, we show the first positive detection of propene (C 3H6) in Titan's stratosphere (5σ significance), finally filling the three-decade gap in the chemical sequence. We retrieve a vertical abundance profile from 100-250 km, that varies slowly with altitude from 2.0 ± 0.8 ppbv at 125 km, to 4.6 ± 1.5 ppbv at 200 km. The abundance of C3H6 is less than both C3H 8 and CH3C2H, and we remark on an emerging paradigm in Titan's hydrocarbon abundances whereby alkanes > alkynes > alkenes within the C2Hx and C3Hx chemical families in the lower stratosphere. More generally, there appears to be much greater ubiquity and relative abundance of triple-bonded species than double-bonded, likely due to the greater resistance of triple bonds to photolysis and chemical attack. © 2013. The American Astronomical Society. All rights reserved.