Jupiter’s auroral-related stratospheric heating and chemistry II: Analysis of IRTF-TEXES spectra measured in December 2014

Sinclair, James; Orton, Glenn S.; Greathouse, T. K.; Fletcher, Leigh N.; Moses, Julianne I.; Hue, V.; Irwin, Patrick G. J.

doi:10.1016/j.icarus.2017.09.016

Cited by 30 publications

(95 citation statements)

References 35 publications

(57 reference statements)

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“…This feature was not present less than 24 hours later ( Figure 2b) and we have ruled out variable atmospheric seeing conditions between these two nights as the source of this intermittent morphology (see Supplementary Figure 2). A similar morphology of the ultraviolet auroral emission, described as the 'duskside active region', has also been observed during periods of enhanced solar-wind pressures and has been attributed to duskside/nightside reconnection associated with the Vasyliunas or Dungey cycles or velocity shears caused by changing flows on the nightside magnetospheric flank 4,5,10 . Indeed, ionosphere-magnetosphere mapping calculations map 73 • N, 155 • W (an example location covered by the duskside feature) to ∼100R J at a local time of 19.0 hr.…”

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confidence: 62%

A brightening of Jupiter’s auroral 7.8-μm CH4 emission during a solar-wind compression

et al. 2019

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Enhanced mid-infrared emission from CH 4 and other stratospheric hydrocarbons have been observed coincident with Jupiter's ultraviolet auroral emission 1-3 , which demonstrates that auroral processes and the neutral stratosphere of Jupiter are coupled. However, the exact nature of this coupling has remained an open question. Here, we present a time series of Subaru-COMICS images of Jupiter at 7.80 µm measured between January 11-14th, February 4-5th and May 17-20th (UT) 2017, which show both the morphology and magnitude of the auroral CH 4 emission to vary on daily timescales in relation to external solar-wind conditions. The southern auroral CH 4 emission increased in brightness temperature (T b) by ∆T b = 3.8 ± 0.9 K between January 11th 15:50 UT-12th 12:57 UT during a predicted solarwind compression. During the same compression, the northern auroral emission exhibited a dusk-side brightening, which mimicks the morphology observed in the ultraviolet auroral emission during periods of enhanced solar-wind pressures 4, 5. These results suggest that changes in external solar wind conditions perturb the jovian magnetosphere such that ener

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confidence: 62%

A brightening of Jupiter’s auroral 7.8-μm CH4 emission during a solar-wind compression

et al. 2019

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“…On Jupiter, stratospheric temperatures are elevated within the auroral oval both by Joule heating and particulate absorption 57 . Future work could address whether the processes heating the atmosphere at nanobar pressures could also influence the temperatures of Saturn’s polar stratosphere at millibar levels but would require a close coupling of thermospheric and stratospheric circulation, chemistry and radiative models that include the influences of aerosols.…”

Section: Discussionmentioning

confidence: 99%

A hexagon in Saturn’s northern stratosphere surrounding the emerging summertime polar vortex

et al. 2018

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Saturn’s polar stratosphere exhibits the seasonal growth and dissipation of broad, warm vortices poleward of ~75° latitude, which are strongest in the summer and absent in winter. The longevity of the exploration of the Saturn system by Cassini allows the use of infrared spectroscopy to trace the formation of the North Polar Stratospheric Vortex (NPSV), a region of enhanced temperatures and elevated hydrocarbon abundances at millibar pressures. We constrain the timescales of stratospheric vortex formation and dissipation in both hemispheres. Although the NPSV formed during late northern spring, by the end of Cassini’s reconnaissance (shortly after northern summer solstice), it still did not display the contrasts in temperature and composition that were evident at the south pole during southern summer. The newly formed NPSV was bounded by a strengthening stratospheric thermal gradient near 78°N. The emergent boundary was hexagonal, suggesting that the Rossby wave responsible for Saturn’s long-lived polar hexagon—which was previously expected to be trapped in the troposphere—can influence the stratospheric temperatures some 300 km above Saturn’s clouds.

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“…The same atmosphere is used here, only we have extended the depth from 200 to

-

88 km, where 0 km is set to where the pressure is equal to 1 bar (Figure ). The atmosphere below 200 km has been generated using temperature‐pressure profiles retrieved from National Aeronautics and Space Administration's Infrared Telescope Facility and the Texas Echelon Cross Echelle Spectrograph Instrument (Sinclair et al, ). Using the temperature and pressure, the ideal gas law is then solved to obtain the total number density.…”

Section: Physical Processes and Model Descriptionmentioning

confidence: 99%

“…Atmospheric density profiles of H

_{2}

, He, CH

_{4}

, and H based on data shown in Maurellis and Cravens () and Sinclair et al (). Also shown is the neutral temperature profile as a function of altitude and pressure.…”

Section: Physical Processes and Model Descriptionmentioning

confidence: 99%

“…We follow up on the promise made in Houston et al (2018) to include energetic sulfur precipitation and oxygen improvements, with proton precipitation being left to a future and very necessary publication. Maurellis and Cravens (2001) and Sinclair et al (2018). Also shown is the neutral temperature profile as a function of altitude and pressure.…”

Section: Physical Processes and Model Descriptionmentioning

confidence: 99%

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Jovian Auroral Ion Precipitation: X‐Ray Production From Oxygen and Sulfur Precipitation

et al. 2020

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Many attempts have been made to model X‐ray emission from both bremsstrahlung and ion precipitation into Jupiter's polar caps. Electron bremsstrahlung modeling has fallen short of producing the total overall power output observed by Earth‐orbit‐based X‐ray observatories. Heavy ion precipitation was able to reproduce strong X‐ray fluxes, but the proposed incident ion energies were very high ( >1 MeV per nucleon). Now with the Juno spacecraft at Jupiter, there have been many measurements of heavy ion populations above the polar cap with energies up to 300–400 keV per nucleon (keV/u), well below the ion energies required by earlier models. Recent work has provided a new outlook on how ion‐neutral collisions in the Jovian atmosphere are occurring, providing us with an entirely new set of impact cross sections. The model presented here simulates oxygen and sulfur precipitation, taking into account the new cross sections, every collision process, the measured ion fluxes above Jupiter's polar aurora, and synthetic X‐ray spectra. We predict X‐ray fluxes, efficiencies, and spectra for various initial ion energies considering opacity effects from two different atmospheres. We demonstrate that an in situ measured heavy ion flux above Jupiter's polar cap is capable of producing over 1 GW of X‐ray emission when some assumptions are made. Comparison of our approximated synthetic X‐ray spectrum produced from in situ particle data with a simultaneous X‐ray spectrum observed by XMM‐Newton shows good agreement for the oxygen part of the spectrum but not for the sulfur part.

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Jupiter’s auroral-related stratospheric heating and chemistry II: Analysis of IRTF-TEXES spectra measured in December 2014

Cited by 30 publications

References 35 publications

A brightening of Jupiter’s auroral 7.8-μm CH4 emission during a solar-wind compression

A brightening of Jupiter’s auroral 7.8-μm CH4 emission during a solar-wind compression

A hexagon in Saturn’s northern stratosphere surrounding the emerging summertime polar vortex

Jovian Auroral Ion Precipitation: X‐Ray Production From Oxygen and Sulfur Precipitation

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