2018
DOI: 10.1029/2018ja025511
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Mapping H3+ Temperatures in Jupiter's Northern Auroral Ionosphere Using VLT‐CRIRES

Abstract: We present a detailed study of the H3+ auroral emissions at Jupiter, using data taken on 31 December 2012 with the long‐slit Echelle spectrometer CRIRES (ESO‐VLT). From this data set the rotational temperature of the H3+ ions in Jupiter's upper atmosphere was calculated using the ratio of the ν2 Q(1,0−) and ν2 Q(3,0−) fundamental emission lines. The entire northern auroral region was observed, providing a highly detailed view of ionospheric temperatures, which were mapped onto polar projections. The temperatur… Show more

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Cited by 26 publications
(29 citation statements)
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“…All the profiles we derive in this current work (including column density and emission intensity but excepting the ion line-of-sight velocity) have been line-of-sight intensity corrected. The computational methods involved in calculating the parameters for this study are described extensively by Johnson et al (2017Johnson et al ( , 2018, and the reader is referred to these works for further details. Figure 2 shows the auroral emission intensity and the ion line-of-sight velocity.…”
Section: Observations and Data Analysismentioning
confidence: 99%
“…All the profiles we derive in this current work (including column density and emission intensity but excepting the ion line-of-sight velocity) have been line-of-sight intensity corrected. The computational methods involved in calculating the parameters for this study are described extensively by Johnson et al (2017Johnson et al ( , 2018, and the reader is referred to these works for further details. Figure 2 shows the auroral emission intensity and the ion line-of-sight velocity.…”
Section: Observations and Data Analysismentioning
confidence: 99%
“…By measuring the normalH3+ emission brightness from the Q (1,0 − ) and R (2,2 − ) lines, it is possible to calculate the normalH3+ temperature, column density and total emission in the same way as has been used previously at both Jupiter and Saturn (e.g. [44,47,58]). Ab initio calculations of the theoretical emission per molecule of normalH3+ provide a theoretical brightness for each line at a given temperature [59].…”
Section: Datamentioning
confidence: 99%
“…Our understanding is limited by our ability to spatially resolve emission from the auroral region, making it difficult to measure the ion currents that flow through the ionosphere or the structure of the underlying thermospheric temperatures that are either driven by these aurora, or potentially drive them. In order to better measure these values, it is essential to increase our measured signal to improve the observed signal-to-noise on the planet, as well as bettering our positioning and observing the aurora in two dimensions, so we can map out the normalH3+ accurately across the entire auroral region, a strategy that has greatly improved our understanding of Jupiter's ionosphere [46,47].…”
Section: Introductionmentioning
confidence: 99%
“…In order to convert these to represent the intensity observed along the ‘surface’ normal, a line-of-sight correction is applied (e.g. [11]).…”
Section: Resultsmentioning
confidence: 99%