Prof. Patrick Irwin

The origin and evolution of saturn's 2011-2012 stratospheric vortex

Icarus 221:2 (2012) 560-586

Authors:

LN Fletcher, BE Hesman, RK Achterberg, PGJ Irwin, G Bjoraker, N Gorius, J Hurley, J Sinclair, GS Orton, J Legarreta, E García-Melendo, A Sánchez-Lavega, PL Read, AA Simon-Miller, FM Flasar

Abstract:

The planet-encircling springtime storm in Saturn's troposphere (December 2010-July 2011, Fletcher, L.N. et al. [2011]. Science 332, 1413-1414; Sánchez-Lavega, A. et al. [2011]. Nature 475, 71-74; Fischer, G. et al. [2011]. Nature 475, 75-77) produced dramatic perturbations to stratospheric temperatures, winds and composition at mbar pressures that persisted long after the tropospheric disturbance had abated. Thermal infrared (IR) spectroscopy from the Cassini Composite Infrared Spectrometer (CIRS), supported by ground-based IR imaging from the VISIR instrument on the Very Large Telescope and the MIRSI instrument on NASA's IRTF, is used to track the evolution of a large, hot stratospheric anticyclone between January 2011 and March 2012. The evolutionary sequence can be divided into three phases: (I) the formation and intensification of two distinct warm airmasses near 0.5. mbar between 25 and 35°N (B1 and B2) between January-April 2011, moving westward with different zonal velocities, B1 residing directly above the convective tropospheric storm head; (II) the merging of the warm airmasses to form the large single 'stratospheric beacon' near 40°N (B0) between April and June 2011, disassociated from the storm head and at a higher pressure (2 mbar) than the original beacons, a downward shift of 1.4 scale heights (approximately 85. km) post-merger; and (III) the mature phase characterised by slow cooling (0.11. ±. 0.01. K/day) and longitudinal shrinkage of the anticyclone since July 2011. Peak temperatures of 221.6. ±. 1.4. K at 2. mbar were measured on May 5th 2011 immediately after the merger, some 80. K warmer than the quiescent surroundings. From July 2011 to the time of writing, B0 remained as a long-lived stable stratospheric phenomenon at 2. mbar, moving west with a near-constant velocity of 2.70. ±. 0.04. deg/day (-24.5. ±. 0.4. m/s at 40°N relative to System III longitudes). No perturbations to visible clouds and hazes were detected during this period.With no direct tracers of motion in the stratosphere, we use thermal windshear calculations to estimate clockwise peripheral velocities of 200-400m/s at 2mbar around B0. The peripheral velocities of the two original airmasses were smaller (70-140m/s). In August 2011, the size of the vortex as defined by the peripheral collar was 65° longitude (50,000km in diameter) and 25° latitude. Stratospheric acetylene (C 2H 2) was uniformly enhanced by a factor of three within the vortex, whereas ethane (C 2H 6) remained unaffected. The passage of B0 generated a new band of warm stratospheric emission at 0.5mbar at its northern edge, and there are hints of warm stratospheric structures associated with the beacons at higher altitudes (p<0.1mbar) than can be reliably observed by CIRS nadir spectroscopy. Analysis of the zonal windshear suggests that Rossby wave perturbations from the convective storm could have propagated vertically into the stratosphere at this point in Saturn's seasonal cycle, one possible source of energy for the formation of these stratospheric anticyclones. © 2012 Elsevier Inc.

A Gemini ground-based transmission spectrum of WASP-29b: a featureless spectrum from 515 to 720nm

(2012)

Authors:

NP Gibson, S Aigrain, JK Barstow, TM Evans, LN Fletcher, PGJ Irwin

EChO

Experimental Astronomy Springer Science and Business Media LLC 34:2 (2012) 311-353

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 de 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, V Batista, P Bernath, B Bézard, P Bordé, LR Brown, A Cassan, C Cavarroc, A Ciaravella, C 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 Sánchez-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

EChO

Experimental Astronomy Springer Nature 34:2 (2012) 311-353

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 de 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, V Batista, P Bernath, B Bézard, P Bordé, LR Brown, A Cassan, C Cavarroc, A Ciaravella, C 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 Sánchez-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

The application of new methane line absorption data to Gemini-N/NIFS and KPNO/FTS observations of Uranus' near-infrared spectrum

Icarus 220:2 (2012) 369-382

Authors:

PGJ Irwin, C de Bergh, R Courtin, B Bézard, NA Teanby, GR Davis, LN Fletcher, GS Orton, SB Calcutt, D Tice, J Hurley

Abstract:

New line data describing the absorption of CH 4 and CH 3D from 1.26 to 1.71μm (Campargue, A., Wang, L., Mondelain, D., Kassi, S., Bézard, B., Lellouch, E., Coustenis, A., de Bergh, C., Hirtzig, M., Drossart, P. [2012]. Icarus 219, 110-128), building upon previous papers by Campargue et al. (Campargue, A., Wang, L., Kassi, S., Masat, M., Votava, O. [2010]. J. Quant. Spectrosc. Radiat. Transfer 111, 1141-1151; Wang, L., Kassi, S., Campargue, A. [2010]. J. Quant. Spectrosc. Radiat. Transfer 111, 1130-1140; Wang, L., Kassi, S., Liu, A.W., Hu, S.M., Campargue, A. [2011]. J. Quant. Spectrosc. Radiat. Transfer 112, 937-951)) have been applied to the analysis of Gemini-N/NIFS observations of Uranus made in 2010 and compared with earlier disc-averaged observations made by KPNO/FTS in 1982. The new line data are found to improve greatly the fit to the observed spectra and present a huge advance over previous methane absorption tables by allowing us to determine the CH 3D/CH 4 ratio and also start to break the degeneracy between methane abundance and cloud top height. The best fits are obtained if the cloud particles in the main cloud deck at the 2-3bar level become less scattering with wavelength across the 1.4-1.6μm region and we have modelled this variation here by varying the extinction cross-section and single-scattering albedo of the particles.Applying the new line data to the NIFS spectra of Uranus, we determine a new estimate of the CH 3D/CH 4 ratio of 2.9-0.5+0.9×10-4, which is consistent with the estimate of de Bergh et al. (de Bergh, C., Lutz, B.L., Owen, T., Brault, J., Chauville, J. [1986]. Astrophys. J. 311, 501-510) of 3.6-2.8+3.6×10-4, made by fitting a disc-averaged KPNO/FTS spectrum measured in 1982, but much better constrained. The NIFS observations made in 2010 have been disc-averaged and compared with the 1982 KPNO/FTS spectrum and found to be in excellent agreement.Using k-tables fitted to the new line data, the central meridian observations of Uranus' H-band spectrum (1.49-1.64μm) made by Gemini-N/NIFS in 2010 have been reanalyzed. The use of the new methane absorption coefficients and the modified scattering properties of the cloud particles in the main cloud deck appears to break the degeneracy between cloud height and methane abundance immediately above it in this spectral region and we find that both vary with latitude across Uranus' disc. Overall, we find that the main cloud deck becomes higher, but thinner from equator to poles, with a local maximum in cloud top height in the circumpolar zones at 45°N and 45°S. At the same time, using the 'D' temperature pressure profile of Lindal et al. (Lindal, G.F., Lyons, J.R., Sweetnam, D.N., Eshleman, V.R., Hinson, D.P. [1987]. J. Geophys. Res. 92, 14987-15001) and a deep methane abundance of 1.6% (Baines, K.H., Mickelson, M.E., Larson, L.E., Ferguson, D.W. [1995]. Icarus 144, 328-340) we find that the relative humidity of methane is high near the equator (~60%) and decreases sharply towards the poles, except near the circumpolar zone at 45°N, which has brightened steadily since 2007, and where there is a local maximum in methane relative humidity. In tests conducted with the warmer 'F1' profile of Sromovsky et al. (2011) we find a similar variation of methane abundance above the main cloud, although for this warmer temperature profile this abundance is dependent mostly on the fitted deep methane mole fraction. © 2012 Elsevier Inc.