# Suzaku observation of Jupiter's X-rays around solar maximum

**Authors:** Masaki Numazawa, Yuichiro Ezoe, Takaya Ohashi, Kumi Ishikawa,, Yoshizumi Miyoshi, Tomoki Kimura, Yasunobu Uchiyama, Daikou Shiota, and, Graziella Branduardi-Raymont

arXiv: 1906.06123 · 2019-08-07

## TL;DR

This study used Suzaku observations from 2006 and 2014 to analyze Jupiter's X-ray emissions, confirming inverse-Compton scattering as a key process and examining how solar activity influences high-energy electron behavior in Jupiter's magnetosphere.

## Contribution

It provides new observational evidence of Jupiter's X-ray emissions around solar maximum and analyzes changes in spatial distribution and luminosity related to solar activity.

## Key findings

- Diffuse X-ray emission confirmed in 2014, similar to 2006.
- Point-like emission increased with solar activity.
- Diffuse emission's spatial extent expanded, indicating complex particle dynamics.

## Abstract

We report on results of imaging and spectral studies of X-ray emission from Jupiter observed by Suzaku. In 2006 Suzaku had found diffuse X-ray emission in $1\unicode{x2013}5$ keV associated with Jovian inner radiation belts. It has been suggested that the emission is caused by the inverse-Compton scattering by ultra-relativistic electrons ($ \sim 50 $ MeV) in Jupiter's magnetosphere. To confirm the existence of this emission and to understand its relation to the solar activity, we conducted an additional Suzaku observation in 2014 around the maximum of the 24th solar cycle. As a result, we successfully found again the diffuse emission around Jupiter in $1\unicode{x2013}5$ keV and also point-like emission in $0.4\unicode{x2013}1$ keV. The luminosity of the point-like emission which was probably composed of solar X-ray scattering, charge exchange, or auroral bremsstrahlung emission increased by a factor of $ \sim 5$ with respect to 2006, most likely due to an increase of the solar activity. The diffuse emission spectrum in the $1\unicode{x2013}5$ keV band was well-fitted with a flat power-law function ($ \Gamma = 1.4 \pm 0.1 $) as in the past observation, which supported the inverse-Compton scattering hypothesis. However, its spatial distribution changed from $ \sim 12 \times 4 $ Jovian radius (Rj) to $ \sim 20 \times 7 $ Rj. The luminosity of the diffuse emission increased by a smaller factor of $ \sim 3 $. This indicates that the diffuse emission is not simply responding to the solar activity, which is also known to cause little effect on the distribution of high-energy electrons around Jupiter. Further sensitive study of the spatial and spectral distributions of the diffuse hard X-ray emission is important to understand how high-energy particles are accelerated in Jupiter's magnetosphere.

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1906.06123/full.md

## References

24 references — full list in the complete paper: https://tomesphere.com/paper/1906.06123/full.md

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Source: https://tomesphere.com/paper/1906.06123