Composition and thermal profiles of the Jovian upper atmosphere determined by the Voyager Ultraviolet Stellar Occultation Experiment

Festou, M. C.; Atreya, S. K.; Donahue, T. M.; Sandel, B. R.; Shemansky, D. E.; Broadfoot, A. L.

doi:10.1029/ja086ia07p05715

Cited by 102 publications

(84 citation statements)

References 27 publications

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“…This suggests that thermal conduction alone is an unlikely candidate for the responsible cooling mechanism, especially since, as with the radiative cooling argument, we have made a "best case" scenario by ignoring heating sources. However, the UVS thermal profiles underestimated the thermal gradients near 1 µbar on Jupiter by a factor of 3 (Festou et al 1981, Young et al 1997), so we cannot rule out a similar readjustment here. As on Jupiter, one way to constrain the thermal gradients in this region is by measurements of the temperatures near the homopause from H 2 fluorescence (Liu and Dalgarno 1996), in combination with ground-based and UVS occultations (Yelle et al 1996).…”

Section: Cooling By Conductionmentioning

confidence: 88%

Uranus after Solstice: Results from the 1998 November 6 Occultation

Young

Bosh

Elliot

et al. 2001

Icarus

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We observed a stellar occultation of the star U149 by Uranus from Lowell Observatory and the IRTF on Mauna Kea on November 6, 1998. The temperatures derived from isothermal fits to the Lowell lightcurves are 116.7 ± 7.9 K for immersion, and 124.8 ± 15.5 K for emersion. The secular increase in temperature seen during the period 1977-1983 has reversed. Furthermore, the rate of decrease (≥1.2 K/yr) cannot be explained solely by radiative cooling. Although the temperature structure of Uranus' upper atmosphere may be related to seasonal effects (e.g., the subsolar latitude) or local conditions (e.g., diurnally averaged insolation), these observations suggest nonradiative influences on the temperature, such as adiabatic heating/cooling or thermal conduction.

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Section: Cooling By Conductionmentioning

confidence: 88%

Uranus after Solstice: Results from the 1998 November 6 Occultation

Young

Bosh

Elliot

et al. 2001

Icarus

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“…I0). The current measurements of the hydrocarbon profiles (Voyager data, Festou, et al, 1980), however, would tend to make this shoulder disappear.…”

Section: Ionospherementioning

confidence: 99%

“…stellar occultation data analysis have been presented by Festou, et al (1980). These data yield temperature and atmospheric density profiles from 160km to about 1750km above the ammonia cloud tops.…”

Section: Thermal Structurementioning

confidence: 99%

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The atmosphere and ionosphere of Jupiter

Atreya¹,

Donahue²

1981

Vistas in Astronomy

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The properties of the atmosphere of Jupiter are reviewed in the light of observations carried out by the Voyager mission. Solar occultation measurements in the ultraviolet show that the temperature of the upper atmosphere is II00±200K, an apparent increase of about 30% from the value obtained by the Pioneer mission in 1973. Stellar occultation in the ultraviolet indicate that the temperature gradient in the thermosphere is about IK km -I. These results pose problems for candidate heating mechanisms because the heat input required is large (0.5 ergs cm -2 s -1) and must be deposited at high altitudes. Solar EUV, inertia gravity waves and particle and ion precipitation appear to be unsatisfactory mechanisms for the equatorial thermosphere. Joule heating remains a possibility. For Joule heating to be a viable mechanism, differential wind of several hundred meters per second between the ions and neutrals is required throughout the entire ionosphere. The stellar occultation experiment also provides a determination of the altitude of the homopause and the eddy diffusion coefficient there of about (l-2)xlO6cm2s-l. This result is consistent with the value deduced from the helium 584~ airglow emission rate based on the evidence from infrared data that the He/H 2 ratio is 0.i0± 0.03. A very large solar cycle variation in the atomic hydrogen Lyman alpha airglow emission rate is discussed. The stellar occultation data also provide information concerning hydrocarbons in the atmosphere. The volume mixing ratios of CH 4 and C2H 6 are found to be 2.5xi0 -5 and 2.5xi0 -6 at 5~b level, while the upper limit for C2H 2 at lO~b level is 5xlO -6. Voyager IR data yield the volume mixing ratios deeper in the stratosphere to be (1.4±0.45)xi0 -3, 5xlO -6, and 3xlO -8 to 10 -7 for CH4, C2H 6 and C2H 2 respectively. The CH 4 mixing ratio is thus 1.5±0.5 times the value one would expect for a solar composition ratio of the elements.The equatorial electron density profile determined by Voyager radio occultation can be explained if ion molecule reactions between H + and vibrationally excited H 2 at high temperatures are fast enough. Temperature dependence of these reactions also accounts for an observed ionospheric diurnal variation. The high latitude ionosphere indicates possible precipitation of high energy particles in the region mapped by the Io plasma torus.

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“…The advent of CCDs (or other multi-pixels detectors), enabling measurement of the whole transmission spectrum at once, increased dramatically the capability of stellar occultation versus the use of filters, or scanning spectrometers. The first multi-pixel occultation (to our knowledge) was inaugurated with the ultraviolet spectrometer UVS placed on board the Voyager 1 and 2 missions: in 1979, an occultation of the star alfa Leonis by the atmosphere of Jupiter was observed from a distance of 14 millions km by Voyager 1 in the full range 110-170 nm allowing one to probe the H 2 and methane vertical profiles (Festou et al, 1981). Since then, this technique was fostered at Service d'Aéronomie, in particular for the study of the atmosphere of the planet Mars with the SPICAM instrument.…”

Section: Appendix a A Short History Of The Stellar Occultation Techniquementioning

confidence: 99%

Global ozone monitoring by occultation of stars: an overview of GOMOS measurements on ENVISAT

et al. 2010

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Abstract. GOMOS on ENVISAT (launched in February, 2002) is the first space instrument dedicated to the study of the atmosphere of the Earth by the technique of stellar occultations (Global Ozone Monitoring by Occultation of Stars). Its polar orbit makes good latitude coverage possible. Because it is self-calibrating, it is particularly well adapted to long time trend monitoring of stratospheric species. With 4 spectrometers, the wavelength coverage of 248 nm to 942 nm enables monitoring ozone, H 2 O, NO 2 , NO 3 , air density, aerosol extinction, and O 2 . Two additional fast photometers (with 1 kHz sampling rate) enable the correction of the effects of scintillations, as well as the study of the structure of air density irregularities resulting from gravity waves and turbulence. A high vertical resolution profile of the temperature may also be obtained from the time delay between the red and the blue photometer. Noctilucent clouds (Polar Mesospheric Clouds, PMC) are routinely observed in both polar summers and global observations of OClO and sodium are achieved.The instrument configuration, dictated by the scientific objectives' rationale and technical constraints, is described, together with the typical operations along one orbit, along with the statistics from over 6 years of operation. Typical atmospheric transmission spectra are presented and some retrieval difficulties are discussed, in particular for O 2 and H 2 O.Correspondence to: J. L. Bertaux (bertaux@latmos.ipsl.fr) An overview is presented of a number of scientific results already published or found in more detail as companion papers in the same ACP GOMOS special issue. This paper is particularly intended to provide an incentive for the exploitation of GOMOS data available to the whole scientific community in the ESA data archive, and to help GOMOS data users to better understand the instrument, its capabilities and the quality of its measurements, thus leading to an increase in the scientific return.

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Composition and thermal profiles of the Jovian upper atmosphere determined by the Voyager Ultraviolet Stellar Occultation Experiment

Cited by 102 publications

References 27 publications

Uranus after Solstice: Results from the 1998 November 6 Occultation

Uranus after Solstice: Results from the 1998 November 6 Occultation

The atmosphere and ionosphere of Jupiter

Global ozone monitoring by occultation of stars: an overview of GOMOS measurements on ENVISAT

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