Jupiter&rsquo;s hot spots as observed by JIRAM-Juno: limb-darkening in thermal infrared

Davide Grassi; Alessandro Mura; Alberto Adriani; Giuseppe Sindoni; Christina Plainaki; Federico Tosi; Angelo Olivieri; Giuseppe Piccioni; Pietro Scarica; Francesco Biagiotti; Scott Bolton

doi:https://doi.org/10.5194/egusphere-egu23-2727

[Back] [Session PS6.3]

EGU23-2727

https://doi.org/10.5194/egusphere-egu23-2727

EGU General Assembly 2023

© Author(s) 2023. This work is distributed under
the Creative Commons Attribution 4.0 License.

Jupiter’s hot spots as observed by JIRAM-Juno: limb-darkening in thermal infrared

Davide Grassi¹, Alessandro Mura¹, Alberto Adriani¹, Giuseppe Sindoni², Christina Plainaki^2,1, Federico Tosi¹, Angelo Olivieri², Giuseppe Piccioni¹, Pietro Scarica¹, Francesco Biagiotti^3,1, and Scott Bolton⁴

Davide Grassi et al.

¹INAF, IAPS, Roma, Italy (davide.grassi@inaf.it)
²ASI, Roma, Italy
³Univ. di Roma "Sapienza", Italy
⁴SwRI, San Antonio (TX), USA

The Jupiter InfraRed Auroral Mapper (JIRAM) instrument on board the Juno spacecraft performed multiple observations of the Jupiter North Equatorial Belt (NEB) around the time of 12^th Juno pericenter passage on April 1^st 2018. The data consist in thermal infrared images (the JIRAM filter has a band pass centred around 4.8 μm) and show, among other atmospheric features, two bright hot-spots.

Images of the same areas at different emission angles were used to constraint the trend of the limb darkening function.

Comparison against simulated observations computed for different emission angles, total opacities, single scattering albedo ω₀ and asymmetry parameter g suggest that ω₀~ 0.9 and g ~ 0.32 provide best match with data, with the latter parameter only weakly constrained by JIRAM observations. Then, we computed the ω₀ and g resulting from different size distributions (exploring the effective radius reff and variance v space), taking into account the complex refractive indices of ammonium hydrosulphide by [1] and [2].

Our analysis suggests that neither sets of refractive indices are consistent with JIRAM observations. A more reasonable agreement is found once tholines are adopted, with an effective radius of 0.6 μm. This value is broadly consistent with the mean radius of Hot Spot’s particles estimated by [3] on the basis of Galileo Entry Probe data. While a composition of pure tholine is not realistic for Jupiter conditions, our results indicate that scattering properties of clouds are largely dominated by optical properties of contaminants, as already suggested in [4]. Indeed, a thin (0.01 of total radius) coating of such compound over a NH₄SH particle can effectively mask the optical properties of the latter. An effective radius of 0.4 μm for these coated particles produces the ω₀ and g derived from JIRAM data.

[1] Howett C. J. A. et al., (2007) J. Opt. Soc. Am. B 24, 126-136.

[2] Ferraro J. R et al. (1980) Applied Spectroscopy, 34 (5), 525-533.

[3] Ragent B. et al, (1998), J. Geophys. Res., 103 (E10), 22891– 22909.

[4] Grassi D. et al. (2021) MNRAS, 503(4), 4892-4907.

This work was supported by the Italian Space Agency through ASI-INAF contract 2016-23-H.1-2018.

How to cite: Grassi, D., Mura, A., Adriani, A., Sindoni, G., Plainaki, C., Tosi, F., Olivieri, A., Piccioni, G., Scarica, P., Biagiotti, F., and Bolton, S.: Jupiter’s hot spots as observed by JIRAM-Juno: limb-darkening in thermal infrared, EGU General Assembly 2023, Vienna, Austria, 24–28 Apr 2023, EGU23-2727, https://doi.org/10.5194/egusphere-egu23-2727, 2023.