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766 results on '"Mauk, B. H."'

1. Auroral diagnosis of solar wind interaction with Jupiter's magnetosphere

Author

Yao, Z. H., Bonfond, B., Grodent, D., Chané, E., Dunn, W. R., Kurth, W. S., Connerney, J. E. P., Nichols, J. D., Palmaerts, B., Guo, R. L., Hospodarsky, G. B., Mauk, B. H., Kimura, T., and Bolton, S. J.

Subjects
Physics - Space Physics, Physics - Plasma Physics
Abstract

Although mass and energy in Jupiter's magnetosphere mostly come from the innermost Galilean moon Io's volcanic activities, solar wind perturbations can play crucial roles in releasing the magnetospheric energy and powering aurorae in Jupiter's polar regions. The systematic response of aurora to solar wind compression remains poorly understood. Here we report the analysis of a set of auroral images with contemporaneous in situ magnetopause detections. We distinguish two types of auroral enhancements: a transient localized one and a long-lasting global one. We show that only the latter systematically appears under a compressed magnetopause, while the localized auroral expansion could occur during an expanded magnetopause. Moreover, we directly examine previous theories on how solar wind compressions enhance auroral emissions. Our results demonstrate that auroral morphologies can be diagnostic of solar wind conditions at planets when in situ measurements are not possible.

Published
2020
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2. Electron-Scale Dynamics of the Diffusion Region during Symmetric Magnetic Reconnection in Space

Author

Torbert, R. B., Burch, J. L., Phan, T. D., Hesse, M., Argall, M. R., Shuster, J., Ergun, R. E., Alm, L., Nakamura, R., Genestreti, K., Gershman, D. J., Paterson, W. R., Turner, D. L., Cohen, I., Giles, B. L., Pollock, C. J., Wang, S., Chen, L. -J., Stawarz, Julia, Eastwood, J. P., Hwang, K. - J., Farrugia, C., Dors, I., Vaith, H., Mouikis, C., Ardakani, A., Mauk, B. H., Fuselier, S. A., Russell, C. T., Strangeway, R. J., Moore, T. E., Drake, J. F., Shay, M. A., Khotyaintsev, Yu. V., Lindqvist, P. -A., Baumjohann, W., Wilder, F. D., Ahmadi, N., Dorelli, J. C., Avanov, L. A., Oka, M., Baker, D. N., Fennell, J. F., Blake, J. B., Jaynes, A. N., Contel, O. Le, Petrinec, S. M., Lavraud, B., and Saito, Y.

Subjects
Physics - Space Physics
Abstract

Magnetic reconnection is an energy conversion process important in many astrophysical contexts including the Earth's magnetosphere, where the process can be investigated in-situ. Here we present the first encounter of a reconnection site by NASA's Magnetospheric Multiscale (MMS) spacecraft in the magnetotail, where reconnection involves symmetric inflow conditions. The unprecedented electron-scale plasma measurements revealed (1) super-Alfvenic electron jets reaching 20,000 km/s, (2) electron meandering motion and acceleration by the electric field, producing multiple crescent-shaped structures, (3) spatial dimensions of the electron diffusion region implying a reconnection rate of 0.1-0.2. The well-structured multiple layers of electron populations indicate that, despite the presence of turbulence near the reconnection site, the key electron dynamics appears to be largely laminar., Comment: 4 pages, 3 figures, and supplementary material

Published
2018
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4. Statistical Survey of Interchange Events in the Jovian Magnetosphere Using Juno Observations.

Author

Daly, A., Li, W., Ma, Q., Shen, X.‐C., Capannolo, L., Huang, S., Kurth, W. S., Hospodarsky, G. B., Mauk, B. H., Clark, G., Allegrini, F., and Bolton, S. J.

Subjects
PLASMA waves, PLASMA flow, SOLAR system, PLASMA sources, ELECTRON transport
Abstract

Interchange instability is known to drive fast radial transport of electrons and ions in Jupiter's inner and middle magnetosphere. In this study, we conduct a statistical survey to evaluate the properties of energetic particles and plasma waves during interchange events using Juno data from 2016 to 2023. We present representative examples of interchange events followed by a statistical analysis of the spatial distribution, duration and spatial extent. Our survey indicates that interchange instability is predominant at M‐shells from 6 to 26, peaking near 17 with an average duration of minutes and a corresponding M‐shell width of <∼0.05. During interchange events, the associated plasma waves, such as whistler‐mode, Z‐mode, and electron cyclotron harmonic waves exhibit a distinct preferential location. These findings provide valuable insights into particle transport and the source region of plasma waves in the Jovian magnetosphere, as well as in other magnetized planets within and beyond our solar system. Plain Language Summary: The radial transport of plasma around a magnetized planet is crucial for understanding the underlying magnetospheric dynamics. Jupiter's magnetospheric dynamics are primarily dominated by the rapid rotation and plasma source from Io. This rapid rotation drives the interchange instability, where hot, low‐density plasma is moved toward the inner magnetosphere. During this process, the inward moving flux tube builds up magnetic pressure, potentially leading to the trapping of particles alongside plasma waves. In this study, we present several typical examples of interchange events, and conduct a statistical analysis to explore their spatial distribution, duration and spatial extent, as well as the typical features of the associated plasma waves. This survey provides insights into mass transport, the source of these plasma waves in Jupiter's magnetosphere, with potential implications for other magnetized planets within and beyond our solar system. Key Points: Our statistical survey indicates that interchange events occur over L (or M)‐shells ∼6–26 at Jupiter with a peak occurrence rate at M ∼ 17During interchange events, various types of plasma waves are intensified, each exhibiting a distinct preferential locationThe duration and the corresponding spatial extent of interchange events are analyzed for multiple events [ABSTRACT FROM AUTHOR]

Published
2024
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5. Temporal and Spatial Variability of the Electron Environment at the Orbit of Ganymede as Observed by Juno

Author

Pelcener, S., primary, André, N., additional, Nénon, Q., additional, Rabia, J., additional, Rojo, M., additional, Kamran, A., additional, Blanc, M., additional, Louarn, P., additional, Penou, E., additional, Santos‐Costa, D., additional, Allegrini, F., additional, Ebert, R. W., additional, Wilson, R. J., additional, Szalay, J., additional, Mauk, B. H., additional, Paranicas, C., additional, Clark, G., additional, Bagenal, F., additional, and Bolton, S., additional

Published
2024
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6. Energetic Charged Particle Measurements During Juno's Two Close Io Flybys.

Author

Paranicas, C., Mauk, B. H., Clark, G., Kollmann, P., Nénon, Q., Ebert, R. W., Szalay, J. R., Sulaiman, A. H., Connerney, J. E. P., and Bolton, S.

Subjects
*ATMOSPHERE of Jupiter, *LUNAR surface, *PARTICLE detectors, *JUNO (Space probe), *PROTON beams, *ELECTRON beams, *ELECTRON energy loss spectroscopy
Abstract

On days 2023‐364 and 2024‐034, the Juno spacecraft made close passages of Jupiter's moon Io, at altitudes of about 1,500 km. Data obtained from the first flyby, when the spacecraft was on magnetic field lines connected to both Jupiter and Io, revealed deep flux decreases. In addition, Juno's energetic particle detectors observed tens to hundreds of keV electron and proton beams. Such beams could be generated near Jupiter on field lines associated with Io. The second encounter occurred in the plasma wake and a more modest flux decrease was observed. Furthermore, data from both encounters suggest a spatially extensive decrease in >1 MeV electrons that includes regions inward of Io's orbit. In the immediate vicinity of Io, signatures of absorption likely dominate the data whereas diffusion and wave‐particle interactions are expected to be needed to understand MeV electron data in the wider spatial region around Io. Plain Language Summary: Jupiter's magnetospheric plasma overtakes Io in its orbit. This causes a cavity to be formed over the hemisphere of Io that leads its orbital motion. Within this cavity subtle details of the plasma and energetic charged particle environment can be extracted from the signal, usually dominated by radiation at these distances. Examples include beams traveling in the direction from Jupiter to the moon, with little evidence of reflection at Io. Another major finding of this work is that there is a large region both along Io's orbit and even radially inward of it with a lower level of MeV electron flux. Guided by previous modeling, the most likely candidates for shaping the data are absorption by the moon, wave‐particle interactions that can scatter particles into Jupiter's atmosphere, and diffusion. Key Points: Deep flux decreases over Io and in its immediate wake caused by losses to the moon's surface were observed in Juno JEDI dataJuno JEDI detected narrow field‐aligned beams of electrons and protons directed toward Io's north poleMoon absorption and wave‐particle interactions may explain the loss of >1 MeV electrons that extend both inward and outward of Io's orbit [ABSTRACT FROM AUTHOR]

Published
2024
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7. Generation and Impacts of Whistler‐Mode Waves During Energetic Electron Injections in Jupiter's Outer Radiation Belt.

Author

Ma, Q., Li, W., Zhang, X.‐J., Bortnik, J., Shen, X.‐C., Daly, A., Kurth, W. S., Mauk, B. H., Allegrini, F., Connerney, J. E. P., Bagenal, F., and Bolton, S. J.

Subjects
RADIATION belts, JUNO (Space probe), ELECTRONS, RELATIVISTIC electrons, ELECTRON scattering, ELECTRON distribution
Abstract

Energetic particle injections are commonly observed in Jupiter's magnetosphere and have important impacts on the radiation belts. We evaluate the roles of electron injections in the dynamics of whistler‐mode waves and relativistic electrons using Juno measurements and wave‐particle interaction modeling. The Juno spacecraft observed injected electron flux bursts at energies up to 300 keV at M shell ∼11 near the magnetic equator during perijove‐31. The electron injections are related to chorus wave bursts at 0.05–0.5 fce frequencies, where fce is the electron gyrofrequency. The electron pitch angle distributions are anisotropic, peaking near 90° pitch angle, and the fluxes are high during injections. We calculate the whistler‐mode wave growth rates using the observed electron distributions and linear theory. The frequency spectrum of the wave growth rate is consistent with that of the observed chorus magnetic intensity, suggesting that the observed electron injections provide free energy to generate whistler‐mode chorus waves. We further use quasilinear theory to model the impacts of chorus waves on 0.1–10 MeV electrons. Our modeling shows that the chorus waves could cause the pitch angle scattering loss of electrons at <1 MeV energies and accelerate relativistic electrons at multiple MeV energies in Jupiter's outer radiation belt. The electron injections also provide an important seed population at several hundred keV energies to support the acceleration to higher energies. Our wave‐particle interaction modeling demonstrates the energy flow from the electron injections to the relativistic electron population through the medium of whistler‐mode waves in Jupiter's outer radiation belt. Key Points: Chorus wave generation due to electron injections is demonstrated by their correlative occurrence and wave instability analysisWhistler‐mode waves scatter electrons into the loss cone and cause diffuse auroral precipitation with intensities of 60–160 erg/cm2/sChorus waves cause local acceleration of MeV electrons in several days, further aided by the seed electron population from injections [ABSTRACT FROM AUTHOR]

Published
2024
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8. Juno Plasma Wave Observations at Europa

Author

Kurth, W. S., primary, Wilkinson, D. R., additional, Hospodarsky, G. B., additional, Santolík, O., additional, Averkamp, T. F., additional, Sulaiman, A. H., additional, Menietti, J. D., additional, Connerney, J. E. P., additional, Allegrini, F., additional, Mauk, B. H., additional, and Bolton, S. J., additional

Published
2023
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9. Plasma Wave and Particle Dynamics During Interchange Events in the Jovian Magnetosphere Using Juno Observations

Author

Daly, A., primary, Li, W., additional, Ma, Q., additional, Shen, X.‐C., additional, Yoon, P. H., additional, Menietti, J. D., additional, Kurth, W. S., additional, Hospodarsky, G. B., additional, Mauk, B. H., additional, Clark, G., additional, Allegrini, F., additional, Connerney, J. E. P., additional, and Bolton, S. J., additional

Published
2023
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11. A radiation belt of energetic protons located between Saturn and its rings

Author

Roussos, E., Kollmann, P., Krupp, N., Kotova, A., Regoli, L., Paranicas, C., Mitchell, D. G., Krimigis, S. M., Hamilton, D., Brandt, P., Carbary, J., Christon, S., Dialynas, K., Dandouras, I., Hill, M. E., Ip, W. H., Jones, G. H., Livi, S., Mauk, B. H., Palmaerts, B., Roelof, E. C., Rymer, A., Sergis, N., and Smith, H. T.

Published
2018

13. Dynamics of Saturn's Magnetosphere from MIMI during Cassini's Orbital Insertion

Author

Krimigis, S. M., Mitchell, D. G., Hamilton, D. C., Krupp, N., Livi, S., Roelof, E. C., Dandouras, J., Armstrong, T. P., Mauk, B. H., Paranicas, C., Brandt, P. C., Bolton, S., Cheng, A. F., Choo, T., Gloeckler, G., Hayes, J., Hsieh, K. C., Jaskulek, S., Keath, E. P., Kirsch, E., Kusterer, M., Lagg, A., Lanzerotti, L. J., LaVallee, D., Manweiler, J., McEntire, R. W., Rasmuss, W., Saur, J., Turner, F. S., Williams, D. J., and Woch, J.

Published
2005

14. Juno's Multi‐Instruments Observations During the Flybys of Auroral Bright Spots in Jupiter's Polar Aurorae

Author

Haewsantati, K., primary, Bonfond, B., additional, Wannawichian, S., additional, Gladstone, G. R., additional, Hue, V., additional, Greathouse, T. K., additional, Grodent, D., additional, Yao, Z., additional, Gérard, J.‐C., additional, Guo, R., additional, Elliott, S., additional, Mauk, B. H., additional, Clark, G., additional, Gershman, D., additional, Kotsiaros, S., additional, Kurth, W. S., additional, Connerney, J., additional, Szalay, J. R., additional, and Phriksee, A., additional

Published
2023
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15. A comparison of energetic particle energization observations at MMS and injections at Van Allen Probes.

Author

Chepuri, S. N. F., Jaynes, A. N., Turner, D. L., Gabrielse, C., Baker, D. N., Mauk, B. H., Cohen, I. J., Leonard, T., Blake, J. B., Fennell, J. F., Eastwood, Jonathan, Buzulukova, Natalia, Huang, Shiyong, and Yao, Zhonghua

Subjects
GEOSYNCHRONOUS orbits, MAGNETOSPHERE, SPACE vehicles
Abstract

In this study, we examine particle energization and injections that show energetic electron enhancements at both MMS in the magnetotail and Van Allen Probes in the inner magnetosphere. Observing injections along with a corresponding flow burst allows us to better understand injections overall. Searching for suitable events, we found that only a small number of events at MMS had corresponding injections that penetrated far enough into the inner magnetosphere to observe with Van Allen Probes. With the four suitable events we did find, we compared the energy spectra at the two spacecraft and mapped the boundary of where the injection entered the inner magnetosphere. We found that, among these injections in the inner magnetosphere, the electron flux did not increase above ~400 keV, similar to previous results, but the corresponding signatures in the tail observed increased fluxes at 600 keV or higher. There does not appear to be a comparable flux increase at Van Allen Probes and MMS for a given event. None of our injections included ion enhancements at Van Allen Probes, but one included an ion injection at geosynchronous orbit in the GOES spacecraft. All of our injections were dispersed at Van Allen Probes, and we were therefore able to map an estimate of the injection boundary. All of the injections occurred in the premidnight sector. Although we found some events where particle energizations in the tail are accompanied by inner magnetospheric injections, we do not find a statistical link between the two. [ABSTRACT FROM AUTHOR]

Published
2024
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16. Autogenous and efficient acceleration of energetic ions upstream of Earth’s bow shock

Author

Turner, D. L., Wilson, III, L. B., Liu, T. Z., Cohen, I. J., Schwartz, S. J., Osmane, A., Fennell, J. F., Clemmons, J. H., Blake, J. B., Westlake, J., Mauk, B. H., Jaynes, A. N., Leonard, T., Baker, D. N., Strangeway, R. J., Russell, C. T., Gershman, D. J., Avanov, L., Giles, B. L., Torbert, R. B., Broll, J., Gomez, R. G., Fuselier, S. A., and Burch, J. L.

Published
2018
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17. How Bi‐Modal are Jupiter’s Main Aurora Zones?

Author

Mauk, B. H., primary, Szalay, J. R., additional, Allegrini, F., additional, Bagenal, F., additional, Bolton, S. J., additional, Clark, G., additional, Connerney, J. E. P., additional, Gladstone, G. R., additional, Haggerty, D. K., additional, Kollmann, P., additional, Kurth, W. S., additional, Paranicas, C. P., additional, and Sulaiman, A. H., additional

Published
2023
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18. Energetic proton acceleration by EMIC waves in Io’s footprint tail

Author

Clark, G., primary, Szalay, J. R., additional, Sulaiman, A. H., additional, Saur, J., additional, Kollmann, P., additional, Mauk, B. H., additional, Paranicas, C., additional, Hue, V., additional, Greathouse, T., additional, Allegrini, F., additional, Glocer, A., additional, Garcia-Sage, K., additional, and Bolton, S., additional

Published
2023
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20. Juno's Multi-Instruments Observations During the Flybys of Auroral Bright Spots in Jupiter's Polar Aurorae

Author

Haewsantati, K., Bonfond, B., Wannawichian, S., Gladstone, G. R., Hue, V., Greathouse, T. K., Grodent, D., Yao, Z., Gérard, J. C., Guo, R., Elliott, S., Mauk, B. H., Clark, G., Gershman, D., Kotsiaros, S., Kurth, W. S., Connerney, J., Szalay, J. R., Phriksee, A., Haewsantati, K., Bonfond, B., Wannawichian, S., Gladstone, G. R., Hue, V., Greathouse, T. K., Grodent, D., Yao, Z., Gérard, J. C., Guo, R., Elliott, S., Mauk, B. H., Clark, G., Gershman, D., Kotsiaros, S., Kurth, W. S., Connerney, J., Szalay, J. R., and Phriksee, A.

Abstract

Juno's arrival at Jupiter in 2016 revealed unprecedented details about Jupiter's ultraviolet aurorae thanks to its unique suite of remote sensing and in situ instruments. Here we present results from in situ observations during Juno flybys above specific bright auroral spots in Jupiter's polar aurora. We compare data observed by Juno-UVS, JEDI, JADE, Waves, and MAG instruments when Juno was magnetically connected to bright polar auroral spots (or their immediate vicinity) during perijove 3 (PJ3), PJ15, and PJ33. The highly energetic particles observed by JEDI show enhancements dominated by upward electrons, which suggests that the particle acceleration region takes place below the spacecraft. Moreover, brightness and upward particle flux were higher for the northern bright spot in PJ3 than the southern spots found in PJ15 and PJ33. In addition, we notice the intensification of whistler-mode waves at the time of the particle enhancements, suggesting that wave-particle interactions contribute to the acceleration of particles that cause the UV aurorae. The MAG data reveal magnetic perturbations during the PJ3 spot detection by Juno, which suggests the presence of significant field-aligned electric currents. While the stable positions of the bright spots in System III suggest that the phenomenon is fixed to the planet's rotation, the presence of field-aligned currents leaves the possibility of an origin rooted much farther in the magnetosphere.

Published
2023

21. Electron-scale measurements of magnetic reconnection in space

Author

Burch, J. L., Torbert, R. B., Phan, T. D., Chen, L.-J., Moore, T. E., Ergun, R. E., Eastwood, J. P., Gershman, D. J., Cassak, P. A., Argall, M. R., Wang, S., Hesse, M., Pollock, C. J., Giles, B. L., Nakamura, R., Mauk, B. H., Fuselier, S. A., Russell, C. T., Strangeway, R. J., Drake, J. F., Shay, M. A., Khotyaintsev, Yu. V., Lindqvist, P.-A., Marklund, G., Wilder, F. D., Young, D. T., Torkar, K., Goldstein, J., Dorelli, J. C., Avanov, L. A., Oka, M., Baker, D. N., Jaynes, A. N., Goodrich, K. A., Cohen, I. J., Turner, D. L., Fennell, J. F., Blake, J. B., Clemmons, J., Goldman, M., Newman, D., Petrinec, S. M., Trattner, K. J., Lavraud, B., Reiff, P. H., Baumjohann, W., Magnes, W., Steller, M., Lewis, W., Saito, Y., Coffey, V., and Chandler, M.

Published
2016

24. Energetic Electrons Near Europa From Juno JEDI Data.

Author

Paranicas, C., Mauk, B. H., Clark, G., Kollmann, P., Westlake, J., Hibbitts, K., Nordheim, T., Hand, K., Brennan, M., Connerney, J. E. P., and Bolton, S.

Subjects
*PARTICLE detectors, *OPTICAL remote sensing, *JUNO (Space probe), *ELECTRONS, *EUROPA (Satellite), *CHEMICAL weathering
Abstract

Optical remote sensing observations have suggested that the top layer of Europa's icy surface is heavily affected by external weathering agents. To model and understand these effects, it is necessary to characterize the environment as fully as possible. In this paper, we focus on one agent in the environment (energetic electrons). We show Juno electron data from its 2022 Europa flyby and other time periods. While the Juno sensor used here (Jupiter Energetic Particle Detector Instrument) was not designed to obtain high quality electron data in an intense radiation environment, it is possible to extract information such as how Europa blocks energetic particles from accessing some of the surrounding space. The decrease in charged particle flux in Europa's wake provides an upper limit on the precipitation fluxes of the same particles. We also report that electron pitch angle distributions near Europa for the single energy channel considered here are time variable and not isotropic. Plain Language Summary: We present energetic electron data obtained when the Juno spacecraft crossed the plasma wake of the moon Europa in 2022. A major goal of this work is to estimate the amount of blockage of MeV electrons near the moon to inform radiation estimates for future Europa orbiters and landers. While the Jupiter Energetic Particle Detector Instrument does not directly detect particles between 1 and 20 MeV, using knowledge gained since the instrument began obtaining data we were able to estimate that about 80% of the particles in question are blocked by Europa in its wake at low altitude. Research on the weathering of Europa's surface by electrons is also discussed. Key Points: Jupiter Energetic Particle Detector Instrument electron data relevant to Europa are presentedWe estimate Europa's blockage causes an ∼80% reduction of ∼1–20 MeV electrons in the immediate plasma wakePitch angle distributions are computed from 70 keV electron data and show time variability [ABSTRACT FROM AUTHOR]

Published
2023
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26. Discrete and broadband electron acceleration in Jupiters powerful aurora

Author

Mauk, B. H., Haggerty, D. K., Paranicas, C., Clark, G., Kollmann, P., Rymer, A. M., Bolton, S. J., Levin, S. M., Adriani, A., Allegrini, F., Bagenal, F., Bonfond, B., Connerney, J. E. P., Gladstone, G. R., Kurth, W. S., McComas, D. J., and Valek, P.

Subjects
Auroras -- Observations, Jupiter (Planet) -- Observations, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): B. H. Mauk (corresponding author) [1]; D. K. Haggerty [1]; C. Paranicas [1]; G. Clark [1]; P. Kollmann [1]; A. M. Rymer [1]; S. J. Bolton [2]; S. M. [...]

Published
2017
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27. Driver of Energetic Electron Precipitation in the Vicinity of Ganymede

Author

Li, W., primary, Ma, Q., additional, Shen, X.‐C., additional, Zhang, X.‐J., additional, Mauk, B. H., additional, Clark, G., additional, Allegrini, F., additional, Kurth, W. S., additional, Hospodarsky, G. B., additional, Sulaiman, A., additional, Nordheim, T. A., additional, and Bolton, S. J., additional

Published
2022
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29. Energetic Charged Particle Observations During Juno's Close Flyby of Ganymede

Author

Clark, G., primary, Kollmann, P., additional, Mauk, B. H., additional, Paranicas, C., additional, Haggerty, D., additional, Rymer, A., additional, Smith, H. T., additional, Saur, J., additional, Allegrini, F., additional, Duling, S., additional, Ebert, R. W., additional, Kurth, W. S., additional, Gladstone, R., additional, Greathouse, T. K., additional, Li, W., additional, Bagenal, F., additional, Connerney, J. E. P., additional, Bolton, S., additional, Szalay, J. R., additional, Sulaiman, A. H., additional, Hansen, C. J., additional, and Turner, D. L., additional

Published
2022
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30. Juno Plasma Wave Observations at Ganymede

Author

Kurth, W. S., primary, Sulaiman, A. H., additional, Hospodarsky, G. B., additional, Menietti, J. D., additional, Mauk, B. H., additional, Clark, G., additional, Allegrini, F., additional, Valek, P., additional, Connerney, J. E. P., additional, Waite, J. H., additional, Bolton, S. J., additional, Imai, M., additional, Santolik, O., additional, Li, W., additional, Duling, S., additional, Saur, J., additional, and Louis, C., additional

Published
2022
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31. A comparison of energetic particle energization observations MMS at and injections at Van Allen Probes

Author

Chepuri, S. N. F., Jaynes, A. N., Turner, D. L., Gabrielse, C., Baker, D. N., Mauk, B. H., Cohen, I. J., Leonard, T., Blake, J. B., and Fennell, J. F.

Subjects
Astronomy and Astrophysics
Abstract

In this study, we examine particle energization and injections that show energetic electron enhancements at both MMS in the magnetotail and Van Allen Probes in the inner magnetosphere. Observing injections along with a corresponding flow burst allows us to better understand injections overall. Searching for suitable events, we found that only a small number of events at MMS had corresponding injections that penetrated far enough into the inner magnetosphere to observe with Van Allen Probes. With the four suitable events we did find, we compared the energy spectra at the two spacecraft and mapped the boundary of where the injection entered the inner magnetosphere. We found that, among these injections in the inner magnetosphere, the electron flux did not increase above ∼400 keV, similar to previous results, but the corresponding signatures in the tail observed increased fluxes at 600 keV or higher. There does not appear to be a comparable flux increase at Van Allen Probes and MMS for a given event. None of our injections included ion enhancements at Van Allen Probes, but one included an ion injection at geosynchronous orbit in the GOES spacecraft. All of our injections were dispersed at Van Allen Probes, and we were therefore able to map an estimate of the injection boundary. All of the injections occurred in the premidnight sector. Although we found some events where particle energizations in the tail are accompanied by inner magnetospheric injections, we do not find a statistical link between the two.

Published
2023

32. On the Relation Between Auroral Morphologies and Compression Conditions of Jupiter's Magnetopause: Observations From Juno and the Hubble Space Telescope

Author

Yao, Z. H., primary, Bonfond, B., additional, Grodent, D., additional, Chané, E., additional, Dunn, W. R., additional, Kurth, W. S., additional, Connerney, J. E. P., additional, Nichols, J. D., additional, Palmaerts, B., additional, Guo, R. L., additional, Hospodarsky, G. B., additional, Mauk, B. H., additional, Kimura, T., additional, and Bolton, S. J., additional

Published
2022
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33. Fundamental Plasma Processes in Saturn's Magnetosphere

Author

Mauk, B. H., Hamilton, D. C., Hill, T. W., Hospodarsky, G. B., Johnson, R. E., Paranicas, C., Roussos, E., Russell, C. T., Shemansky, D. E., Sittler, E. C., Jr., Thorne, R. M., Dougherty, Michele K., editor, Esposito, Larry W., editor, and Krimigis, Stamatios M., editor

Published
2009
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34. The Fly’s Eye Energetic Particle Spectrometer (FEEPS) Sensors for the Magnetospheric Multiscale (MMS) Mission

Author

Blake, J. B., primary, Mauk, B. H., additional, Baker, D. N., additional, Carranza, P., additional, Clemmons, J. H., additional, Craft, J., additional, Crain, W. R., additional, Crew, A., additional, Dotan, Y., additional, Fennell, J. F., additional, Friedel, R. H., additional, Friesen, L. M., additional, Fuentes, F., additional, Galvan, R., additional, Ibscher, C., additional, Jaynes, A., additional, Katz, N., additional, Lalic, M., additional, Lin, A. Y., additional, Mabry, D. M., additional, Nguyen, T., additional, Pancratz, C., additional, Redding, M., additional, Reeves, G. D., additional, Smith, S., additional, Spence, H. E., additional, and Westlake, J., additional

Published
2016
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35. The Energetic Particle Detector (EPD) Investigation and the Energetic Ion Spectrometer (EIS) for the Magnetospheric Multiscale (MMS) Mission

Author

Mauk, B. H., primary, Blake, J. B., additional, Baker, D. N., additional, Clemmons, J. H., additional, Reeves, G. D., additional, Spence, H. E., additional, Jaskulek, S. E., additional, Schlemm, C. E., additional, Brown, L. E., additional, Cooper, S. A., additional, Craft, J. V., additional, Fennell, J. F., additional, Gurnee, R. S., additional, Hammock, C. M., additional, Hayes, J. R., additional, Hill, P. A., additional, Ho, G. C., additional, Hutcheson, J. C., additional, Jacques, A. D., additional, Kerem, S., additional, Mitchell, D. G., additional, Nelson, K. S., additional, Paschalidis, N. P., additional, Rossano, E., additional, Stokes, M. R., additional, and Westlake, J. H., additional

Published
2016
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36. Precipitating Electron Energy Flux and Characteristic Energies in Jupiter's Main Auroral Region as Measured by Juno/JEDI

Author

Clark, G, Tao, C, Mauk, B. H, Nichols, J, Saur, J, Bunce, E. J, Allegrini, F, Gladstone, R, Bagenal, F, Bolton, S, Bonfond, B, Connerney, J, Ebert, R. W, Gershman, D. J, Haggerty, D, Kimura, T, Kollmann, P, Kotsiaros, S, Kurth, W. S, Levin, S, McComas, D. J, Murakami, G, Paranicas, C, Rymer, A, and Valek, P

Subjects
Lunar And Planetary Science And Exploration
Abstract

The relationship between electron energy flux and the characteristic energy of electron distributions in the main auroral loss cone bridges the gap between predictions made by theory and measurements just recently available from Juno. For decades such relationships have been inferred from remote sensing observations of the Jovian aurora, primarily from the Hubble Space Telescope, and also more recently from Hisaki. However, to infer these quantities, remote sensing techniques had to assume properties of the Jovian atmospheric structure - leading to uncertainties in their profile. Juno's arrival and subsequent auroral passes have allowed us to obtain these relationships unambiguously for the first time, when the spacecraft passes through the auroral acceleration region. Using Juno /Jupiter Energetic particle Detector Instrument (JEDI), an energetic particle instrument, we present these relationships for the 30-kiloelectronvolts to 1-megaelectronvolts electron population. Observations presented here show that the electron energy flux in the loss cone is a nonlinear function of the characteristic or mean electron energy and supports both the predictions from Knight (1973, https://doi.org/10.1016/0032-0633(73)90093-7) and magnetohydrodynamic turbulence acceleration theories (e.g., Saur et al., 2003, https://doi.org/10.1029/2002GL015761). Finally, we compare the in situ analyses of Juno with remote Hisaki observations and use them to help constrain Jupiter's atmospheric profile. We find a possible solution that provides the best agreement between these data sets is an atmospheric profile that more efficiently transports the hydrocarbons to higher altitudes. If this is correct, it supports the previously published idea (e.g., Parkinson et al., 2006, https://doi.org/10.1029/2005JE002539) that precipitating electrons increase the hydrocarbon eddy diffusion coefficients in the auroral regions.

Published
2018
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37. Jovian Auroral Electron Precipitation Budget—A Statistical Analysis of Diffuse, Mono‐Energetic, and Broadband Auroral Electron Distributions

Author

Salveter, A., Saur, J., Clark, G., Mauk, B. H., 1 Institute of Geophysics and Meteorology University of Cologne Cologne Germany, and 2 The Johns Hopkins University Applied Physics Laboratory Laurel MD USA

Subjects
Juno, ddc:523, Geophysics, Space and Planetary Science, Jupiter, particle distribution, auroral precipitation budget
Abstract

Recent observations by the Juno spacecraft have shown that electrons contributing to Jupiter's main auroral emission appear to be frequently characterized by broadband electron distributions, but also less often mono‐energetic electron distributions are observed as well. In this work, we quantitatively derive the occurrence rates of the various electron distributions contributing to Jupiter's aurora. We perform a statistical analysis of electrons measured by the JEDI‐instrument within 30–1,200 keV from Juno's first 20 orbits. We determine the electron distributions, either pancake, field‐aligned, mono‐energetic, or broadband, through energy and pitch angles to associate various acceleration mechanisms. The statistical analysis shows that field‐aligned accelerated electrons at magnetic latitudes greater than 76° are observed in 87.6% ± 7.2% of the intervals time averaged over the dipole L‐shells according the main oval. Pancake distributions, indicating diffuse aurora, are prominent at smaller magnetic latitudes (, Plain Language Summary: With the Juno spacecraft arriving in the magnetosphere of Jupiter, first flyby particle measurements have changed the knowledge about the developing process of Jupiter's intense aurora. The observations of auroral particles show a stochastic behavior rather than a preference for specific energy. Our statistical analysis of the first 20 flybys at Jupiter compares the occurrence of different particle distributions and highlights the importance of different generation theories for Jupiter's aurora. A generation via stochastic rather than mono‐energetic behavior is deduced and supports previous observations., Key Points: We present a statistical study of Jupiter's auroral electrons within 30–1,200 keV based on Juno's first 20 perijoves. Broadband electron distributions dominates Jupiter's main auroral zone as they are observed in 93% ± 3% of the intervals studied here. Dominance of broadband distributions underlines the importance of a turbulent or stochastic acceleration process., Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659, Universität zu Köln http://dx.doi.org/10.13039/501100008001, https://lasp.colorado.edu/home/mop/files/2015/02/CoOrd_systems7.pdf, https://pds-ppi.igpp.ucla.edu/mission/JUNO/JNO/JEDI, https://lasp.colorado.edu/home/mop/files/2020/04/20190412_Imai_MagFootReader_UIowa_rev.pdf

Published
2022

38. The Fly’s Eye Energetic Particle Spectrometer (FEEPS) Sensors for the Magnetospheric Multiscale (MMS) Mission

Author

Blake, J. B., Mauk, B. H., Baker, D. N., Carranza, P., Clemmons, J. H., Craft, J., Crain, Jr., W. R., Crew, A., Dotan, Y., Fennell, J. F., Friedel, R. H., Friesen, L. M., Fuentes, F., Galvan, R., Ibscher, C., Jaynes, A., Katz, N., Lalic, M., Lin, A. Y., Mabry, D. M., Nguyen, T., Pancratz, C., Redding, M., Reeves, G. D., Smith, S., Spence, H. E., and Westlake, J.

Published
2016
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39. The Energetic Particle Detector (EPD) Investigation and the Energetic Ion Spectrometer (EIS) for the Magnetospheric Multiscale (MMS) Mission

Author

Mauk, B. H., Blake, J. B., Baker, D. N., Clemmons, J. H., Reeves, G. D., Spence, H. E., Jaskulek, S. E., Schlemm, C. E., Brown, L. E., Cooper, S. A., Craft, J. V., Fennell, J. F., Gurnee, R. S., Hammock, C. M., Hayes, J. R., Hill, P. A., Ho, G. C., Hutcheson, J. C., Jacques, A. D., Kerem, S., Mitchell, D. G., Nelson, K. S., Paschalidis, N. P., Rossano, E., Stokes, M. R., and Westlake, J. H.

Published
2016
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40. Jupiter's Low‐Altitude Auroral Zones: Fields, Particles, Plasma Waves, and Density Depletions

Author

Sulaiman, A. H., primary, Mauk, B. H., additional, Szalay, J. R., additional, Allegrini, F., additional, Clark, G., additional, Gladstone, G. R., additional, Kotsiaros, S., additional, Kurth, W. S., additional, Bagenal, F., additional, Bonfond, B., additional, Connerney, J. E. P., additional, Ebert, R. W., additional, Elliott, S. S., additional, Gershman, D. J., additional, Hospodarsky, G. B., additional, Hue, V., additional, Lysak, R. L., additional, Masters, A., additional, Santolík, O., additional, Saur, J., additional, and Bolton, S. J., additional

Published
2022
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42. Magnetosphere Imaging Instrument (MIMI) on the Cassini Mission to Saturn/Titan

Author

Krimigis, S. M., Mitchell, D. G., Hamilton, D. C., Livi, S., Dandouras, J., Jaskulek, S., Armstrong, T. P., Boldt, J. D., Cheng, A. F., Gloeckler, G., Hayes, J. R., Hsieh, K. C., Ip, W.-H., Keath, E. P., Kirsch, E., Krupp, N., Lanzerotti, L. J., Lundgren, R., Mauk, B. H., McEntire, R. W., Roelof, E. C., Schlemm, C. E., Tossman, B. E., Wilken, B., Williams, D. J., and Russell, Christopher T., editor

Published
2004
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43. Magnetospheric and Plasma Science with Cassini-Huygens

Author

Blanc, M., Bolton, S., Bradley, J., Burton, M., Cravens, T. E., Dandouras, I., Dougherty, M. K., Festou, M. C., Feynman, J., Johnson, R. E., Gombosi, T. G., Kurth, W. S., Liewer, P. C., Mauk, B. H., Maurice, S., Mitchell, D., Neubauer, F. M., Richardson, J. D., Shemansky, D. E., Sittler, E. C., Tsurutani, B. T., Zarka, Ph., Esposito, L. W., Grün, E., Gurnett, D. A., Kliore, A. J., Krimigis, S. M., Southwood, D., Waite, J. H., Young, D. T., and Russell, Christopher T., editor

Published
2003
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45. Jupiter's Low-Altitude Auroral Zones: Fields, Particles, Plasma Waves, and Density Depletions

Author

Sulaiman, A. H., Mauk, B. H., Szalay, J. R., Allegrini, F., Clark, G., Gladstone, G. R., Kotsiaros, S., Kurth, W. S., Bagenal, F., Bonfond, B., Connerney, J. E. P., Ebert, R. W., Elliott, S. S., Gershman, D. J., Hospodarsky, G. B., Hue, V, Lysak, R. L., Masters, A., Santolik, O., Saur, J., Bolton, S. J., Sulaiman, A. H., Mauk, B. H., Szalay, J. R., Allegrini, F., Clark, G., Gladstone, G. R., Kotsiaros, S., Kurth, W. S., Bagenal, F., Bonfond, B., Connerney, J. E. P., Ebert, R. W., Elliott, S. S., Gershman, D. J., Hospodarsky, G. B., Hue, V, Lysak, R. L., Masters, A., Santolik, O., Saur, J., and Bolton, S. J.

Abstract

The Juno spacecraft's polar orbits have enabled direct sampling of Jupiter's low-altitude auroral field lines. While various data sets have identified unique features over Jupiter's main aurora, they are yet to be analyzed altogether to determine how they can be reconciled and fit into the bigger picture of Jupiter's auroral generation mechanisms. Jupiter's main aurora has been classified into distinct zones, based on repeatable signatures found in energetic electron and proton spectra. We combine fields, particles, and plasma wave data sets to analyze Zone-I and Zone-II, which are suggested to carry upward and downward field-aligned currents, respectively. We find Zone-I to have well-defined boundaries across all data sets. H+ and/or H-3(+) cyclotron waves are commonly observed in Zone-I in the presence of energetic upward H+ beams and downward energetic electron beams. Zone-II, on the other hand, does not have a clear poleward boundary with the polar cap, and its signatures are more sporadic. Large-amplitude solitary waves, which are reminiscent of those ubiquitous in Earth's downward current region, are a key feature of Zone-II. Alfvenic fluctuations are most prominent in the diffuse aurora and are repeatedly found to diminish in Zone-I and Zone-II, likely due to dissipation, at higher altitudes, to energize auroral electrons. Finally, we identify significant electron density depletions, by up to 2 orders of magnitude, in Zone-I, and discuss their important implications for the development of parallel potentials, Alfvenic dissipation, and radio wave generation.

Published
2022

46. Energetic Charged Particle Observations During Juno's Close Flyby of Ganymede

Author

Clark, G., Kollmann, P., Mauk, B. H., Paranicas, C., Haggerty, D., Rymer, A., Smith, H. T., Saur, J., Allegrini, F., Duling, S., Ebert, R. W., Kurth, W. S., Gladstone, R., Greathouse, T. K., Li, W., Bagenal, F., Connerney, J. E. P., Bolton, S., Szalay, J. R., Sulaiman, A. H., Hansen, C. J., Turner, D. L., Clark, G., Kollmann, P., Mauk, B. H., Paranicas, C., Haggerty, D., Rymer, A., Smith, H. T., Saur, J., Allegrini, F., Duling, S., Ebert, R. W., Kurth, W. S., Gladstone, R., Greathouse, T. K., Li, W., Bagenal, F., Connerney, J. E. P., Bolton, S., Szalay, J. R., Sulaiman, A. H., Hansen, C. J., and Turner, D. L.

Abstract

On 7 June 2021, NASA's Juno mission obtained unique measurements of Ganymede's magnetosphere during a close flyby that brought the spacecraft within similar to 1,000 km of its surface. Here Jupiter Energetic particle Detector Instrument observations are presented and analyzed. The electron pitch angle distributions reveal distinct regions of Ganymede's magnetosphere that can be characterized as inbound and outbound magnetospheric boundaries, a magnetotail/wake region, and Ganymede's open field line region. Evidence for energy dependent electron pitch angle structuring is also documented both outside and within Ganymede's magnetosphere. Electron precipitation is observed and mapped to Ganymede's surface along Juno's magnetic footpoint.

Published
2022

47. Juno Plasma Wave Observations at Ganymede

Author

Kurth, W. S., Sulaiman, A. H., Hospodarsky, G. B., Menietti, J. D., Mauk, B. H., Clark, G., Allegrini, F., Valek, P., Connerney, J. E. P., Waite, J. H., Bolton, S. J., Imai, M., Santolik, O., Li, W., Duling, S., Saur, J., Louis, C., Kurth, W. S., Sulaiman, A. H., Hospodarsky, G. B., Menietti, J. D., Mauk, B. H., Clark, G., Allegrini, F., Valek, P., Connerney, J. E. P., Waite, J. H., Bolton, S. J., Imai, M., Santolik, O., Li, W., Duling, S., Saur, J., and Louis, C.

Abstract

The Juno Waves instrument measured plasma waves associated with Ganymede's magnetosphere during its flyby on 7 June, day 158, 2021. Three distinct regions were identified including a wake, and nightside and dayside regions in the magnetosphere distinguished by their electron densities and associated variability. The magnetosphere includes electron cyclotron harmonic emissions including a band at the upper hybrid frequency, as well as whistler-mode chorus and hiss. These waves likely interact with energetic electrons in Ganymede's magnetosphere by pitch angle scattering and/or accelerating the electrons. The wake is accentuated by low-frequency turbulence and electrostatic solitary waves. Radio emissions observed before and after the flyby likely have their source in Ganymede's magnetosphere.

Published
2022

48. A Comprehensive Set of Juno In Situ and Remote Sensing Observations of the Ganymede Auroral Footprint

Author

Hue, V., Szalay, J. R., Greathouse, T. K., Bonfond, B., Kotsiaros, S., Louis, C. K., Sulaiman, A., Clark, G., Allegrini, F., Gladstone, G. R., Paranicas, C., Versteeg, M. H., Mura, A., Moirano, A., Gershman, D. J., Bolton, S. J., Connerney, J.E.P., Davis, M. W., Ebert, R. W., Gérard, J.‐C., Giles, R. S., Grodent, D. C., Imai, M., Kammer, J. A., Kurth, W. S., Lamy, L., Mauk, B. H., Hue, V., Szalay, J. R., Greathouse, T. K., Bonfond, B., Kotsiaros, S., Louis, C. K., Sulaiman, A., Clark, G., Allegrini, F., Gladstone, G. R., Paranicas, C., Versteeg, M. H., Mura, A., Moirano, A., Gershman, D. J., Bolton, S. J., Connerney, J.E.P., Davis, M. W., Ebert, R. W., Gérard, J.‐C., Giles, R. S., Grodent, D. C., Imai, M., Kammer, J. A., Kurth, W. S., Lamy, L., and Mauk, B. H.

Abstract

Jupiter’s satellite auroral footprints are a manifestation of the satellite-magnetosphere interaction of the Galilean moons. Juno’s polar elliptical orbit enables crossing the magnetic flux tubes connecting each Galilean moons with their associated auroral emission. Juno’s payload allows measuring the fields and particle population in the flux tubes while remotely sensing their associated auroral emissions. During its thirtieth perijove, Juno crossed the flux tube directly connected to Ganymede’s leading footprint spot, a unique event in the entire Juno prime mission. Juno revealed a highly-structured precipitating electron flux, up to 316 mW/m2, while measuring both a small perturbation in the magnetic field azimuthal component and small Poynting flux, with an estimated total downward current of 4.2 ± 1.2 kA. Based on the evolution of the footprint morphology and the field and particle measurements, Juno transited for the first time through a region connected to the transhemispheric electron beam of the Ganymede footprint.

Published
2022

49. Driver of Energetic Electron Precipitation in the Vicinity of Ganymede.

Author

Li, W., Ma, Q., Shen, X.‐C., Zhang, X.‐J., Mauk, B. H., Clark, G., Allegrini, F., Kurth, W. S., Hospodarsky, G. B., Sulaiman, A., Nordheim, T. A., and Bolton, S. J.

Subjects
JUNO (Space probe), ELECTRONS, ELECTROMAGNETIC waves, P-waves (Seismology), LATITUDE, MAGNETIC fields
Abstract

The driver of energetic electron precipitation into Ganymede's atmosphere has been an outstanding open problem. During the Juno flyby of Ganymede on 7 June 2021, Juno observed significant downward‐going electron fluxes inside the bounce loss cone of Ganymede's polar magnetosphere. Concurrently, Juno detected intense whistler‐mode waves, both in the quasi‐parallel and highly oblique directions with respect to the magnetic field line. We use quasi‐linear model to quantify energetic electron precipitation driven by quasi‐parallel and very oblique whistler‐mode waves, respectively, in the vicinity of Ganymede. The data‐model comparison indicates that in Ganymede's lower‐latitude (higher‐latitude) polar region, quasi‐parallel whistler‐mode waves play a dominant role in precipitating higher‐energy electrons above ∼100s eV (∼1 keV), whereas highly oblique waves are important for precipitating lower‐energy electrons below 100s eV (∼1 keV). Our result provides new evidence of whistler‐mode waves as a potential primary driver of precipitating energetic electrons into Ganymede's atmosphere. Plain Language Summary: During the Juno flyby of Ganymede on 7 June 2021, the Juno spacecraft detected energetic electrons precipitating into Ganymede's atmosphere. Simultaneously, Juno detected intense electromagnetic whistler‐mode waves in the vicinity of Ganymede. We use a physics‐based model to quantify the role of the observed whistler‐mode waves in energetic electron precipitation. The comparison between the Juno observation and modeling results reveals that whistler‐mode waves potentially play a dominant role in precipitating energetic electrons into Ganymede's atmosphere over a broad energy range from tens of eV to several hundred keV. Our findings are potentially important for understanding the loss process of energetic electrons in Ganymede's magnetosphere, as well as the generation of Ganymede's diffuse aurora. Key Points: We provide new evidence of whistler‐mode waves as a potential primary driver of precipitating energetic electrons into Ganymede's atmosphereThis finding is potentially important for the generation of aurora and the loss of energetic electrons in the vicinity of GanymedeJuno observations and quasi‐linear modeling are used to quantify energetic electron precipitation driven by whistler‐mode waves [ABSTRACT FROM AUTHOR]

Published
2023
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50. Loss of Energetic Ions Comprising the Ring Current Populations of Jupiter's Middle and Inner Magnetosphere

Author

Mauk, B. H., primary, Allegrini, F., additional, Bagenal, F., additional, Bolton, S. J., additional, Clark, G., additional, Connerney, J. E. P., additional, Gershman, D. J., additional, Haggerty, D. K., additional, Hue, V., additional, Imai, M., additional, Kollmann, P., additional, Kurth, W. S., additional, Nénon, Q., additional, Paranicas, C. P., additional, Rymer, A. M., additional, Smith, H. T., additional, and Sulaiman, A. H., additional

Published
2022
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