Your search keyword '"Strobel DF"' showing total 17 results

1. Haze heats Pluto's atmosphere yet explains its cold temperature.

Author

Zhang X, Strobel DF, and Imanaka H

Abstract

Pluto's atmosphere is cold and hazy. Recent observations have shown it to be much colder than predicted theoretically, suggesting an unknown cooling mechanism. Atmospheric gas molecules, particularly water vapour, have been proposed as a coolant; however, because Pluto's thermal structure is expected to be in radiative-conductive equilibrium, the required water vapour would need to be supersaturated by many orders of magnitude under thermodynamic equilibrium conditions. Here we report that atmospheric hazes, rather than gases, can explain Pluto's temperature profile. We find that haze particles have substantially larger solar heating and thermal cooling rates than gas molecules, dominating the atmospheric radiative balance from the ground to an altitude of 700 kilometres, above which heat conduction maintains an isothermal atmosphere. We conclude that Pluto's atmosphere is unique among Solar System planetary atmospheres, as its radiative energy equilibrium is controlled primarily by haze particles instead of gas molecules. We predict that Pluto is therefore several orders of magnitude brighter at mid-infrared wavelengths than previously thought-a brightness that could be detected by future telescopes.

Published

2017

2. Orbital apocenter is not a sufficient condition for HST/STIS detection of Europa's water vapor aurora.

Author

Roth L, Retherford KD, Saur J, Strobel DF, Feldman PD, McGrath MA, and Nimmo F

Subjects

Exobiology methods, Hydrogen analysis, Hydrogen chemistry, Ice, Oxygen analysis, Oxygen chemistry, Telescopes, Water chemistry, Extraterrestrial Environment, Jupiter, Steam, Water analysis

Abstract

We report far-ultraviolet observations of Jupiter's moon Europa taken by Space Telescope Imaging Spectrograph (STIS) of the Hubble Space Telescope (HST) in January and February 2014 to test the hypothesis that the discovery of a water vapor aurora in December 2012 by local hydrogen (H) and oxygen (O) emissions with the STIS originated from plume activity possibly correlated with Europa's distance from Jupiter through tidal stress variations. The 2014 observations were scheduled with Europa near the apocenter similar to the orbital position of its previous detection. Tensile stresses on south polar fractures are expected to be highest in this orbital phase, potentially maximizing the probability for plume activity. No local H and O emissions were detected in the new STIS images. In the south polar region where the emission surpluses were observed in 2012, the brightnesses are sufficiently low in the 2014 images to be consistent with any H2O abundance from (0-5)×10(15) cm(-2). Large high-latitude plumes should have been detectable by the STIS, independent of the observing conditions and geometry. Because electron excitation of water vapor remains the only viable explanation for the 2012 detection, the new observations indicate that although the same orbital position of Europa for plume activity may be a necessary condition, it is not a sufficient condition. However, the December 2012 detection of coincident HI Lyman-α and OI 1304-Å emission surpluses in an ∼200-km high region well separated above Europa's limb is a firm result and not invalidated by our 2014 STIS observations.

Published

2014

3. An equatorial oscillation in Saturn's middle atmosphere.

Author

Fouchet T, Guerlet S, Strobel DF, Simon-Miller AA, Bézard B, and Flasar FM

Abstract

The middle atmospheres of planets are driven by a combination of radiative heating and cooling, mean meridional motions, and vertically propagating waves (which originate in the deep troposphere). It is very difficult to model these effects and, therefore, observations are essential to advancing our understanding of atmospheres. The equatorial stratospheres of Earth and Jupiter oscillate quasi-periodically on timescales of about two and four years, respectively, driven by wave-induced momentum transport. On Venus and Titan, waves originating from surface-atmosphere interaction and inertial instability are thought to drive the atmosphere to rotate more rapidly than the surface (superrotation). However, the relevant wave modes have not yet been precisely identified. Here we report infrared observations showing that Saturn has an equatorial oscillation like those found on Earth and Jupiter, as well as a mid-latitude subsidence that may be associated with the equatorial motion. The latitudinal extent of Saturn's oscillation shows that it obeys the same basic physics as do those on Earth and Jupiter. Future highly resolved observations of the temperature profile together with modelling of these three different atmospheres will allow us determine the wave mode, the wavelength and the wave amplitude that lead to middle atmosphere oscillation.

Published

2008

4. The dust halo of Saturn's largest icy moon, Rhea.

Author

Jones GH, Roussos E, Krupp N, Beckmann U, Coates AJ, Crary F, Dandouras I, Dikarev V, Dougherty MK, Garnier P, Hansen CJ, Hendrix AR, Hospodarsky GB, Johnson RE, Kempf S, Khurana KK, Krimigis SM, Krüger H, Kurth WS, Lagg A, McAndrews HJ, Mitchell DG, Paranicas C, Postberg F, Russell CT, Saur J, Seiss M, Spahn F, Srama R, Strobel DF, Tokar R, Wahlund JE, Wilson RJ, Woch J, and Young D

Abstract

Saturn's moon Rhea had been considered massive enough to retain a thin, externally generated atmosphere capable of locally affecting Saturn's magnetosphere. The Cassini spacecraft's in situ observations reveal that energetic electrons are depleted in the moon's vicinity. The absence of a substantial exosphere implies that Rhea's magnetospheric interaction region, rather than being exclusively induced by sputtered gas and its products, likely contains solid material that can absorb magnetospheric particles. Combined observations from several instruments suggest that this material is in the form of grains and boulders up to several decimetres in size and orbits Rhea as an equatorial debris disk. Within this disk may reside denser, discrete rings or arcs of material.

Published

2008

5. Io's atmospheric response to eclipse: UV aurorae observations.

Author

Retherford KD, Spencer JR, Stern SA, Saur J, Strobel DF, Steffl AJ, Gladstone GR, Weaver HA, Cheng AF, Parker JW, Slater DC, Versteeg MH, Davis MW, Bagenal F, Throop HB, Lopes RM, Reuter DC, Lunsford A, Conard SJ, Young LA, and Moore JM

Abstract

The New Horizons (NH) spacecraft observed Io's aurora in eclipse on four occasions during spring 2007. NH Alice ultraviolet spectroscopy and concurrent Hubble Space Telescope ultraviolet imaging in eclipse investigate the relative contribution of volcanoes to Io's atmosphere and its interaction with Jupiter's magnetosphere. Auroral brightness and morphology variations after eclipse ingress and egress reveal changes in the relative contribution of sublimation and volcanic sources to the atmosphere. Brightnesses viewed at different geometries are best explained by a dramatic difference between the dayside and nightside atmospheric density. Far-ultraviolet aurora morphology reveals the influence of plumes on Io's electrodynamic interaction with Jupiter's magnetosphere. Comparisons to detailed simulations of Io's aurora indicate that volcanoes supply 1 to 3% of the dayside atmosphere.

Published

2007

6. Titan's atmospheric temperatures, winds, and composition.

Author

Flasar FM, Achterberg RK, Conrath BJ, Gierasch PJ, Kunde VG, Nixon CA, Bjoraker GL, Jennings DE, Romani PN, Simon-Miller AA, Bézard B, Coustenis A, Irwin PG, Teanby NA, Brasunas J, Pearl JC, Segura ME, Carlson RC, Mamoutkine A, Schinder PJ, Barucci A, Courtin R, Fouchet T, Gautier D, Lellouch E, Marten A, Prangé R, Vinatier S, Strobel DF, Calcutt SB, Read PL, Taylor FW, Bowles N, Samuelson RE, Orton GS, Spilker LJ, Owen TC, Spencer JR, Showalter MR, Ferrari C, Abbas MM, Raulin F, Edgington S, Ade P, and Wishnow EH

Subjects

Atmosphere, Carbon Monoxide, Extraterrestrial Environment, Spacecraft, Temperature, Wind, Hydrocarbons, Methane, Nitriles, Saturn

Abstract

Temperatures obtained from early Cassini infrared observations of Titan show a stratopause at an altitude of 310 kilometers (and 186 kelvin at 15 degrees S). Stratospheric temperatures are coldest in the winter northern hemisphere, with zonal winds reaching 160 meters per second. The concentrations of several stratospheric organic compounds are enhanced at mid- and high northern latitudes, and the strong zonal winds may inhibit mixing between these latitudes and the rest of Titan. Above the south pole, temperatures in the stratosphere are 4 to 5 kelvin cooler than at the equator. The stratospheric mole fractions of methane and carbon monoxide are (1.6 +/- 0.5) x 10(-2) and (4.5 +/- 1.5) x 10(-5), respectively.

Published

2005

7. Temperatures, winds, and composition in the saturnian system.

Author

Flasar FM, Achterberg RK, Conrath BJ, Pearl JC, Bjoraker GL, Jennings DE, Romani PN, Simon-Miller AA, Kunde VG, Nixon CA, Bézard B, Orton GS, Spilker LJ, Spencer JR, Irwin PG, Teanby NA, Owen TC, Brasunas J, Segura ME, Carlson RC, Mamoutkine A, Gierasch PJ, Schinder PJ, Showalter MR, Ferrari C, Barucci A, Courtin R, Coustenis A, Fouchet T, Gautier D, Lellouch E, Marten A, Prangé R, Strobel DF, Calcutt SB, Read PL, Taylor FW, Bowles N, Samuelson RE, Abbas MM, Raulin F, Ade P, Edgington S, Pilorz S, Wallis B, and Wishnow EH

Subjects

Atmosphere, Carbon, Extraterrestrial Environment, Hydrogen, Methane, Spacecraft, Spectrum Analysis, Temperature, Wind, Saturn

Abstract

Stratospheric temperatures on Saturn imply a strong decay of the equatorial winds with altitude. If the decrease in winds reported from recent Hubble Space Telescope images is not a temporal change, then the features tracked must have been at least 130 kilometers higher than in earlier studies. Saturn's south polar stratosphere is warmer than predicted from simple radiative models. The C/H ratio on Saturn is seven times solar, twice Jupiter's. Saturn's ring temperatures have radial variations down to the smallest scale resolved (100 kilometers). Diurnal surface temperature variations on Phoebe suggest a more porous regolith than on the jovian satellites.

Published

2005

8. Jupiter's atmospheric composition from the Cassini thermal infrared spectroscopy experiment.

Author

Kunde VG, Flasar FM, Jennings DE, Bézard B, Strobel DF, Conrath BJ, Nixon CA, Bjoraker GL, Romani PN, Achterberg RK, Simon-Miller AA, Irwin P, Brasunas JC, Pearl JC, Smith MD, Orton GS, Gierasch PJ, Spilker LJ, Carlson RC, Mamoutkine AA, Calcutt SB, Read PL, Taylor FW, Fouchet T, Parrish P, Barucci A, Courtin R, Coustenis A, Gautier D, Lellouch E, Marten A, Prangé R, Biraud Y, Ferrari C, Owen TC, Abbas MM, Samuelson RE, Raulin F, Ade P, Césarsky CJ, Grossman KU, and Coradini A

Subjects

Acetylene, Atmosphere, Ethane, Extraterrestrial Environment, Spacecraft, Spectrum Analysis, Temperature, Carbon Dioxide, Hydrocarbons, Hydrogen Cyanide, Jupiter

Abstract

The Composite Infrared Spectrometer observed Jupiter in the thermal infrared during the swing-by of the Cassini spacecraft. Results include the detection of two new stratospheric species, the methyl radical and diacetylene, gaseous species present in the north and south auroral infrared hot spots; determination of the variations with latitude of acetylene and ethane, the latter a tracer of atmospheric motion; observations of unexpected spatial distributions of carbon dioxide and hydrogen cyanide, both considered to be products of comet Shoemaker-Levy 9 impacts; characterization of the morphology of the auroral infrared hot spot acetylene emission; and a new evaluation of the energetics of the northern auroral infrared hot spot.

Published

2004

9. Volcanically emitted sodium chloride as a source for Io's neutral clouds and plasma torus.

Author

Lellouch E, Paubert G, Moses JI, Schneider NM, and Strobel DF

Abstract

The atmosphere of Jupiter's satellite Io is extremely tenuous, time variable and spatially heterogeneous. Only a few molecules--SO2, SO and S2--have previously been identified as constituents of this atmosphere, and possible sources include frost sublimation, surface sputtering and active volcanism. Io has been known for almost 30 years to be surrounded by a cloud of Na, which requires an as yet unidentified atmospheric source of sodium. Sodium chloride has been recently proposed as an important atmospheric constituent, based on the detection of chlorine in Io's plasma torus and models of Io's volcanic gases. Here we report the detection of NaCl in Io's atmosphere; it constitutes only approximately 0.3% when averaged over the entire disk, but is probably restricted to smaller regions than SO2 because of its rapid photolysis and surface condensation. Although the inferred abundance of NaCl in volcanic gases is lower than predicted, those volcanic emissions provide an important source of Na and Cl in Io's neutral clouds and plasma torus.

Published

2003

10. Far-ultraviolet imaging spectroscopy of Io's atmosphere with HST/STIS.

Author

Roesler FL, Moos HW, Oliversen RJ, Woodward RC Jr, Retherford KD, Scherb F, McGrath MA, Smyth WH, Feldman PD, and Strobel DF

Subjects

Atmosphere, Magnetics, Spectrophotometry, Ultraviolet, Extraterrestrial Environment, Hydrogen, Jupiter, Oxygen, Sulfur

Abstract

Well-resolved far-ultraviolet spectroscopic images of O I, S I, and previously undetected H ILyman-alpha emission from Io were obtained with the Hubble space telescope imaging spectrograph (STIS). Detected O I and S I lines (1250 to 1500 angstroms) have bright equatorial spots (up to 2.5 kilorayleighs) that shift position with jovian magnetic field orientation; limb glow that is brighter on the hemisphere facing the jovian magnetic equator; and faint diffuse emission extending to approximately 20 Io radii. All O I and S I features brightened by approximately 50 percent in the last two images, concurrently with a ground-based observation of increased iogenic [O I] 6300-angstrom emission. The H ILyman-alpha emission, consisting of a small, approximately 2-kilorayleigh patch near each pole, has a different morphology and time variation.

Published

1999

11. Detection of an oxygen atmosphere on Jupiter's moon Europa.

Author

Hall DT, Strobel DF, Feldman PD, McGrath MA, and Weaver HA

Subjects

Atmosphere, Electrons, Magnetics, Spectrum Analysis, Extraterrestrial Environment, Jupiter, Oxygen analysis, Solar System

Abstract

Europa, the second large satellite out from Jupiter, is roughly the size of Earth's Moon, but unlike the Moon, it has water ice on its surface. There have been suggestions that an oxygen atmosphere should accumulate around such a body, through reactions which break up the water molecules and form molecular hydrogen and oxygen. The lighter H2 molecules would escape from Europa relatively easily, leaving behind an atmosphere rich in oxygen. Here we report the detection of atomic oxygen emission from Europa, which we interpret as being produced by the simultaneous dissociation and excitation of atmospheric O2 by electrons from Jupiter's magnetosphere. Europa's molecular oxygen atmosphere is very tenuous, with a surface pressure about 10(-11) that of the Earth's atmosphere at sea level.

Published

1995

12. Extreme ultraviolet observations from voyager 1 encounter with saturn.

Author

Broadfoot AL, Sandel BR, Shemansky DE, Holberg JB, Smith GR, Strobel DF, McConnell JC, Kumar S, Hunten DM, Atreya SK, Donahue TM, Moos HW, Bertaux JL, Blamont JE, Pomphrey RB, and Linick S

Abstract

The global hydrogen Lyman alpha, helium (584 angstroms), and molecular hydrogen band emissions from Saturn are qualitatively similar to those of Jupiter, but the Saturn observations emphasize that the H(2) band excitation mechanism is closely related to the solar flux. Auroras occur near 80 degrees latitude, suggesting Earth-like magnetotail activity, quite different from the dominant Io plasma torus mechanism at Jupiter. No ion emissions have been detected from the magnetosphere of Saturn, but the rings have a hydrogen atmosphere; atomic hydrogen is also present in a torus between 8 and 25 Saturn radii. Nitrogen emission excited by particles has been detected in the Titan dayglow and bright limb scans. Enhancement of the nitrogen emission is observed in the region of interaction between Titan's atmosphere and the corotating plasma in Saturn's plasmasphere. No particle-excited emission has been detected from the dark atmosphere of Titan. The absorption profile of the atmosphere determined by the solar occultation experiment, combined with constraints from the dayglow observations and temperature information, indicate that N(2) is the dominant species. A double layer structure has been detected above Titan's limb. One of the layers may be related to visible layers in the images of Titan.

Published

1981

13. Extreme ultraviolet observations from the voyager 2 encounter with saturn.

Author

Sandel BR, Shemansky DE, Broadfoot AL, Holberg JB, Smith GR, McConnell JC, Strobel DF, Atreya SK, Donahue TM, Moos HW, Hunten DM, Pomphrey RB, and Linick S

Abstract

Combined analysis of helium (584 angstroms) airglow and the atmospheric occultations of the star delta Scorpii imply a vertical mixing parameter in Saturn's upper atmosphere of K (eddy diffusion coefficient) approximately 8 x 10(7) square centimeters per second, an order of magnitude more vigorous than mixing in Jupiter's upper atmosphere. Atmospheric H(2) band absorption of starlight yields a preliminary temperature of 400 K in the exosphere and a temperature near the homopause of approximately 200 K. The energy source for the mid-latitude H(2) band emission still remains a puzzle. Certain auroral emissions can be fully explained in terms of electron impact on H(2), and auroral morphology suggests a link between the aurora and the Saturn kilometric radiation. Absolute optical depths have been determined for the entire C ring andparts of the A and B rings. A new eccentric ringlet has been detected in the C ring. The extreme ultraviolet reflectance of the rings is fairly uniform at 3.5 to 5 percent. Collisions may control the distribution of H in Titan's H torus, which has a total vertical extent of approximately 14 Saturn radii normal to the orbit plane.

Published

1982

14. Extreme ultraviolet observations from voyager 1 encounter with jupiter.

Author

Broadfoot AL, Belton MJ, Takacs PZ, Sandel BR, Shemansky DE, Holberg JB, Ajello JM, Atreya SK, Donahue TM, Moos HW, Bertaux JL, Blamont JE, Strobel DF, McConnell JC, Dalgarno A, Goody R, and McElroy MB

Abstract

Observations of the optical extreme ultraviolet spectrum of the Jupiter planetary system during the Voyager 1 encounter have revealed previously undetected physical processes of significant proportions. Bright emission lines of S III, S IV, and O III indicating an electron temperature of 10(5) K have been identified in preliminary analyses of the Io plasma torus spectrum. Strong auroral atomic and molecular hydrogen emissions have been observed in the polar regions of Jupiter near magnetic field lines that map the torus into the atmosphere of Jupiter. The observed resonance scattering of solar hydrogen Lyman alpha by the atmosphere of Jupiter and the solar occultation experiment suggest a hot thermosphere (>/= 1000 K) wvith a large atomic hydrogen abundance. A stellar occultation by Ganymede indicates that its atmosphere is at most an exosphere.

Published

1979

15. Ultraviolet spectrometer observations of neptune and triton.

Author

Broadfoot AL, Atreya SK, Bertaux JL, Blamont JE, Dessler AJ, Donahue TM, Forrester WT, Hall DT, Herbert F, Holberg JB, Hunter DM, Krasnopolsky VA, Linick S, Lunine JI, McConnell JC, Moos HW, Sandel BR, Schneider NM, Shemansky DE, Smith GR, Strobel DF, and Yelle RV

Abstract

Results from the occultation of the sun by Neptune imply a temperature of 750 +/- 150 kelvins in the upper levels of the atmosphere (composed mostly of atomic and molecular hydrogen) and define the distributions of methane, acetylene, and ethane at lower levels. The ultraviolet spectrum of the sunlit atmosphere of Neptune resembles the spectra of the Jupiter, Saturn, and Uranus atmospheres in that it is dominated by the emissions of H Lyman alpha (340 +/- 20 rayleighs) and molecular hydrogen. The extreme ultraviolet emissions in the range from 800 to 1100 angstroms at the four planets visited by Voyager scale approximately as the inverse square of their heliocentric distances. Weak auroral emissions have been tentatively identified on the night side of Neptune. Airglow and occultation observations of Triton's atmosphere show that it is composed mainly of molecular nitrogen, with a trace of methane near the surface. The temperature of Triton's upper atmosphere is 95 +/- 5 kelvins, and the surface pressure is roughly 14 microbars.

Published

1989

16. Ultraviolet spectrometer observations of uranus.

Author

Broadfoot AL, Herbert F, Holberg JB, Hunten DM, Kumar S, Sandel BR, Shemansky DE, Smith GR, Yelle RV, Strobel DF, Moos HW, Donahue TM, Atreya SK, Bertaux JL, Blamont JE, McConnell JC, Dessler AJ, Linick S, and Springer R

Abstract

Data from solar and stellar occultations of Uranus indicate a temperature of about 750 kelvins in the upper levels of the atmosphere (composed mostly of atomic and molecular hydrogen) and define the distributions of methane and acetylene in the lower levels. The ultraviolet spectrum of the sunlit hemisphere is dominated by emissions from atomic and molecular hydrogen, which are kmown as electroglow emissions. The energy source for these emissions is unknown, but the spectrum implies excitation by low-energy electrons (modeled with a 3-electron-volt Maxwellian energy distribution). The major energy sink for the electrons is dissociation of molecular hydrogen, producing hydrogen atoms at a rate of 10(29) per second. Approximately half the atoms have energies higher than the escape energy. The high temperature of the atmosphere, the small size of Uranus, and the number density of hydrogen atoms in the thermosphere imply an extensive thermal hydrogen corona that reduces the orbital lifetime of ring particles and biases the size distribution toward larger particles. This corona is augmented by the nonthermal hydrogen atoms associated with the electroglow. An aurora near the magnetic pole in the dark hemisphere arises from excitation of molecular hydrogen at the level where its vertical column abundance is about 10(20) per square centimeter with input power comparable to that of the sunlit electroglow (approximately 2x10(11) watts). An initial estimate of the acetylene volume mixing ratio, as judged from measurements of the far ultraviolet albedo, is about 2 x 10(-7) at a vertical column abundance of molecular hydrogen of 10(23) per square centimeter (pressure, approximately 0.3 millibar). Carbon emissions from the Uranian atmosphere were also detected.

Published

1986

17. Extreme ultraviolet observations from voyager 2 encounter with jupiter.

Author

Sandel BR, Shemansky DE, Broadfoot AL, Bertaux JL, Blamont JE, Belton MJ, Ajello JM, Holberg JB, Atreya SK, Donahue TM, Moos HW, Strobel DF, McConnell JC, Dalgarno A, Goody R, McElroy MB, and Takacs PZ

Abstract

Extreme ultraviolet spectral observations of the Jovian planetary system made during the Voyager 2 encounter have extended our knowledge of many of the phenomena and physical processes discovered by the Voyager 1 ultraviolet spectrometer. In the 4 months between encounters, the radiation from Io's plasma torus has increased in intensity by a factor of about 2. This change was accompanied by a decrease in plasma temperature of about 30 percent. The high-latitude auroral zones have been positively associated with the magnetic projection of the plasma torus onto the planet. Emission in molecular hydrogen bands has been detected from the equatorial regions of Jupiter, indicating planetwide electron precipitation. Hydrogen Lyman alpha from the dark side of the planet has been measured at an intensity of about 1 kilorayleigh. An observation of the occultation of alpha Leonis by Jupiter was carried out successfully and the data are being analyzed in detail.

Published

1979