The in-situ exploration of Jupiter’s radiation belts

Roussos, E.; Allanson, Oliver; André, Nicolas; Bertucci, B.; Branduardi‐Raymont, G.; Clark, G.; Dialynas, K.; Dandouras, I.; Desai, R. T.; Futaana, Yoshifumi; Gkioulidou, M.; Jones, G. H.; Kollmann, P.; Kotova, Anna; Kronberg, Elena A.; Krupp, N.; Murakami, Go; Nénon, Quentin; Nordheim, Tom; Palmaerts, Benjamin; Plainaki, C.; Rae, I. J.; Santos-Costa, Daniel; Sarris, T. E.; Shprits, Yuri; Sulaiman, A. H.; Woodfield, E. E.; Wu, X.; Yao, Zhen‐Xing

doi:10.1007/s10686-021-09801-0

Cited by 25 publications

(22 citation statements)

References 169 publications

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“…The analysis could be improved in several aspects: the investigation in the quasitrapping scenario could be refined with a more precise modeling of the electron loss effects; a better understanding of the astrophysical electron sources could allow us to set stronger constraints on the DM parameters. We also want to stress that future Jupiter missions may enable more precise measurements of energetic electron fluxes and the corresponding spectra at different positions [110], which could greatly strengthen the bound. Beyond the analysis we did, we list and outline several other (but not all) exciting avenues to explore the power of Jovian data in new physics searches below.…”

Section: Discussionmentioning

confidence: 99%

Jupiter missions as probes of dark matter

Fan

2022

J. High Energ. Phys.

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Jupiter, the fascinating largest planet in the solar system, has been visited by nine spacecraft, which have collected a significant amount of data about Jovian properties. In this paper, we show that one type of the in situ measurements on the relativistic electron fluxes could be used to probe dark matter (DM) and dark mediator between the dark sector and our visible world. Jupiter, with its immense weight and cool core, could be an ideal capturer for DM with masses around the GeV scale. The captured DM particles could annihilate into long-lived dark mediators such as dark photons, which subsequently decay into electrons and positrons outside Jupiter. The charged particles, trapped by the Jovian magnetic field, have been measured in Jupiter missions such as the Galileo probe and the Juno orbiter. We use the data available to set upper bounds on the cross section of DM scattering off nucleons, σχn, for dark mediators with lifetime of order $$ \mathcal{O} $$ O (0.1–1) s. The results show that data from Jupiter missions already probe regions in the parameter space un- or under-explored by existing DM searches, e.g., constrain σχn of order (10−41–10−39) cm2 for 1 GeV DM dominantly annihilating into e+e− through dark mediators. This study serves as an example and an initial step to explore the full physics potential of the large planetary datasets from Jupiter missions. We also outline several other potential directions related to secondary products of electrons, positron signals and solar axions.

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Section: Discussionmentioning

confidence: 99%

Jupiter missions as probes of dark matter

Fan

2022

J. High Energ. Phys.

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“…The analysis could be improved in several aspects: the investigation in the quasi-trapping scenario could be refined with a more precise modeling of the electron loss effects; a better understanding of the astrophysical electron sources could allow us to set stronger constraints on the DM parameters. We also want to stress that future Jupiter missions may enable more precise measurements of energetic electron fluxes and the corresponding spectra at different positions [106], which could greatly strengthen the bound. Beyond the analysis we did, we list and outline several other (but not all) exciting avenues to explore the power of Jovian data in new physics searches below.…”

Section: Discussionmentioning

confidence: 99%

Jupiter missions as probes of dark matter

Li¹,

Fan²

2022

Preprint

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Jupiter, the fascinating largest planet in the solar system, has been visited by nine spacecraft, which have collected a significant amount of data about Jovian properties. In this paper, we show that one type of the in situ measurements on the relativistic electron fluxes could be used to probe dark matter (DM) and dark mediator between the dark sector and our visible world. Jupiter, with its immense weight and cool core, could be an ideal capturer for DM with masses around or below the GeV scale. The captured DM particles could annihilate into long-lived dark mediators such as dark photons, which subsequently decay into electrons and positrons outside Jupiter. The charged particles, trapped by the Jovian magnetic field, have been measured in Jupiter missions such as the Galileo probe and the Juno orbiter. We use the data available to set upper bounds on the cross section of DM scattering off nucleons, σ χn , for dark mediators with lifetime of order O(0.1 − 1)s. The results show that data from Jupiter missions already probe regions in the parameter space un-or under-explored by existing DM searches, e.g., constrain σ χn of order (10 −40 − 10 −38 ) cm 2 for 1 GeV DM dominantly annihilating into e + e − through dark mediators. This study serves as an example and an initial step to explore the full physics potential of the large planetary datasets from Jupiter missions. We also outline several other potential directions related to secondary products of electrons, positron signals and solar axions.

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“…The more precise magnetosphere and particle source modeling could improve the analysis and strengthen the bounds set on DM models. Future Jupiter missions with advanced particle identification and spectroscopy and better position coverage will further enhance the sensitivity [1351]. We also hope the in situ data of Jupiter or other planets beyond the magnetic field and e ± flux measurements to be utilized to study the beyond Standard Model physics.…”

Section: 24mentioning

confidence: 99%

Feebly-interacting particles: FIPs 2020 workshop report

et al. 2021

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With the establishment and maturation of the experimental programs searching for new physics with sizeable couplings at the LHC, there is an increasing interest in the broader particle and astrophysics community for exploring the physics of light and feebly-interacting particles as a paradigm complementary to a New Physics sector at the TeV scale and beyond. FIPs 2020 has been the first workshop fully dedicated to the physics of feebly-interacting particles and was held virtually from 31 August to 4 September 2020. The workshop has gathered together experts from collider, beam dump, fixed target experiments, as well as from astrophysics, axions/ALPs searches, current/future neutrino experiments, and dark matter direct detection communities to discuss progress in experimental searches and underlying theory models for FIPs physics, and to enhance the cross-fertilisation across different fields. FIPs 2020 has been complemented by the topical workshop “Physics Beyond Colliders meets theory”, held at CERN from 7 June to 9 June 2020. This document presents the summary of the talks presented at the workshops and the outcome of the subsequent discussions held immediately after. It aims to provide a clear picture of this blooming field and proposes a few recommendations for the next round of experimental results.

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The in-situ exploration of Jupiter’s radiation belts

Cited by 25 publications

References 169 publications

Jupiter missions as probes of dark matter

Jupiter missions as probes of dark matter

Jupiter missions as probes of dark matter

Feebly-interacting particles: FIPs 2020 workshop report

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