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Juno Jupiter image

Prof. Patrick Irwin

Professor of Planetary Physics

Research theme

  • Exoplanets and planetary physics

Sub department

  • Atmospheric, Oceanic and Planetary Physics

Research groups

  • Exoplanet atmospheres
  • Planetary atmosphere observation analysis
  • Solar system
patrick.irwin@physics.ox.ac.uk
Telephone: 01865 (2)72083
Atmospheric Physics Clarendon Laboratory, room 306
Personal research page
NEMESIS
  • About
  • Publications

Latitudinal variation of upper tropospheric NH 3 on Saturn derived from Cassini/CIRS far-infrared measurements

Planetary and Space Science (2012)

Authors:

J Hurley, LN Fletcher, PGJ Irwin, SB Calcutt, JA Sinclair, C Merlet
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Observations of upper tropospheric acetylene on Saturn: No apparent correlation with 2000 km-sized thunderstorms

Planetary and Space Science (2012)

Authors:

J Hurley, PGJ Irwin, LN Fletcher, JI Moses, B Hesman, J Sinclair, C Merlet
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EChO - Exoplanet Characterisation Observatory

(2011)

Authors:

G Tinetti, JP Beaulieu, T Henning, M Meyer, G Micela, I Ribas, D Stam, M Swain, O Krause, M Ollivier, E Pace, B Swinyard, A Aylward, R van Boekel, A Coradini, T Encrenaz, I Snellen, MR Zapatero-Osorio, J Bouwman, JY-K Cho, V Coudé du Foresto, T Guillot, M Lopez-Morales, I Mueller-Wodarg, E Palle, F Selsis, A Sozzetti, PAR Ade, N Achilleos, A Adriani, CB Agnor, C Afonso, C Allende Prieto, G Bakos, RJ Barber, M Barlow, P Bernath, B Bezard, P Bordé, LR Brown, A Cassan, C Cavarroc, A Ciaravella, COU Cockell, A Coustenis, C Danielski, L Decin, R De Kok, O Demangeon, P Deroo, P Doel, P Drossart, LN Fletcher, M Focardi, F Forget, S Fossey, P Fouqué, J Frith, M Galand, P Gaulme, JI González Hernández, O Grasset, D Grassi, JL Grenfell, MJ Griffin, CA Griffith, U Grözinger, M Guedel, P Guio, O Hainaut, R Hargreaves, PH Hauschildt, K Heng, D Heyrovsky, R Hueso, P Irwin, L Kaltenegger, P Kervella, D Kipping, TT Koskinen, G Kovács, A La Barbera, H Lammer, E Lellouch, G Leto, M Lopez Morales, MA Lopez Valverde, M Lopez-Puertas, C Lovis, A Maggio, JP Maillard, J Maldonado Prado, JB Marquette, FJ Martin-Torres, P Maxted, S Miller, S Molinari, D Montes, A Moro-Martin, JI Moses, O Mousis, N Nguyen Tuong, R Nelson, GS Orton, E Pantin, E Pascale, S Pezzuto, D Pinfield, E Poretti, R Prinja, L Prisinzano, JM Rees, A Reiners, B Samuel, A Sanchez-Lavega, J Sanz Forcada, D Sasselov, G Savini, B Sicardy, A Smith, L Stixrude, G Strazzulla, J Tennyson, M Tessenyi, G Vasisht, S Vinatier, S Viti, I Waldmann, GJ White, T Widemann, R Wordsworth, R Yelle, Y Yung, SN Yurchenko
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Multispectral imaging observations of Neptune's cloud structure with Gemini-North

Icarus 216:1 (2011) 141-158

Authors:

PGJ Irwin, NA Teanby, GR Davis, LN Fletcher, GS Orton, D Tice, J Hurley, SB Calcutt

Abstract:

Observations of Neptune were made in September 2009 with the Gemini-North Telescope in Hawaii, using the NIFS instrument in the H-band covering the wavelength range 1.477-1.803 μm. Observations were acquired in adaptive optics mode and have a spatial resolution of approximately 0.15-0.25″. The observations were analysed with a multiple-scattering retrieval algorithm to determine the opacity of clouds at different levels in Neptune's atmosphere. We find that the observed spectra at all locations are very well fit with a model that has two thin cloud layers, one at a pressure level of ∼2. bar all over the planet and an upper cloud whose pressure level varies from 0.02 to 0.08. bar in the bright mid-latitude region at 20-40°S to as deep as 0.2. bar near the equator. The opacity of the upper cloud is found to vary greatly with position, but the opacity of the lower cloud deck appears remarkably uniform, except for localised bright spots near 60°S and a possible slight clearing near the equator. A limb-darkening analysis of the observations suggests that the single-scattering albedo of the upper cloud particles varies from ∼0.4 in regions of low overall albedo to close to 1.0 in bright regions, while the lower cloud is consistent with particles that have a single-scattering albedo of ∼0.75 at this wavelength, similar to the value determined for the main cloud deck in Uranus' atmosphere. The Henyey-Greenstein scattering particle asymmetry of particles in the upper cloud deck are found to be in the range g∼ 0.6-0.7 (i.e. reasonably strongly forward scattering).Numerous bright clouds are seen near Neptune's south pole at a range of pressure levels and at latitudes between 60 and 70°S. Discrete clouds were seen at the pressure level of the main cloud deck (∼2. bar) at 60°S on three of the six nights observed. Assuming they are the same feature we estimate the rotation rate at this latitude and pressure to be 13.2 ± 0.1. h. However, the observations are not entirely consistent with a single non-evolving cloud feature, which suggests that the cloud opacity or albedo may vary very rapidly at this level at a rate not seen in any other giant-planet atmosphere. © 2011 Elsevier Inc.
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Saturn's tropospheric composition and clouds from Cassini/VIMS 4.6-5.1μm nightside spectroscopy

Icarus 214:2 (2011) 510-533

Authors:

LN Fletcher, KH Baines, TW Momary, AP Showman, PGJ Irwin, GS Orton, M Roos-Serote, C Merlet

Abstract:

The latitudinal variation of Saturn's tropospheric composition (NH3, PH3 and AsH3) and aerosol properties (cloud altitudes and opacities) are derived from Cassini/VIMS 4.6-5.1μm thermal emission spectroscopy on the planet's nightside (April 22, 2006). The gaseous and aerosol distributions are used to trace atmospheric circulation and chemistry within and below Saturn's cloud decks (in the 1- to 4-bar region). Extensive testing of VIMS spectral models is used to assess and minimise the effects of degeneracies between retrieved variables and sensitivity to the choice of aerosol properties. Best fits indicate cloud opacity in two regimes: (a) a compact cloud deck centred in the 2.5-2.8bar region, symmetric between the northern and southern hemispheres, with small-scale opacity variations responsible for numerous narrow light/dark axisymmetric lanes; and (b) a hemispherically asymmetric population of aerosols at pressures less than 1.4bar (whose exact altitude and vertical structure is not constrained by nightside spectra) which is 1.5-2.0× more opaque in the summer hemisphere than in the north and shows an equatorial maximum between ±10° (planetocentric).Saturn's NH3 spatial variability shows significant enhancement by vertical advection within ±5° of the equator and in axisymmetric bands at 23-25°S and 42-47°N. The latter is consistent with extratropical upwelling in a dark band on the poleward side of the prograde jet at 41°N (planetocentric). PH3 dominates the morphology of the VIMS spectrum, and high-altitude PH3 at p<1.3bar has an equatorial maximum and a mid-latitude asymmetry (elevated in the summer hemisphere), whereas deep PH3 is latitudinally-uniform with off-equatorial maxima near ±10°. The spatial distribution of AsH3 shows similar off-equatorial maxima at ±7° with a global abundance of 2-3ppb. VIMS appears to be sensitive to both (i) an upper tropospheric circulation (sensed by NH3 and upper-tropospheric PH3 and hazes) and (ii) a lower tropospheric circulation (sensed by deep PH3, AsH3 and the lower cloud deck). © 2011 Elsevier Inc.
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