85 citations as recorded by crossref.

1. Candidates for detecting exoplanetary radio emissions generated by magnetosphere—ionosphere coupling J. Nichols
2. Axially Asymmetric Steady State Model of Jupiter's Magnetosphere‐Ionosphere Coupling I. Pensionerov et al.
3. Observations of Jovian polar auroral filaments J. Nichols et al.
4. Magnetosphere and Plasma Science with the Jupiter Icy Moons Explorer A. Masters et al.
5. Asymmetry in the Jovian auroral Lyman‐α line profile due to thermospheric high‐speed flow J. Chaufray et al.
6. Influence of upstream solar wind on thermospheric flows at Jupiter J. Yates et al.
7. A Preliminary Study of Magnetosphere‐Ionosphere‐Thermosphere Coupling at Jupiter: Juno Multi‐Instrument Measurements and Modeling Tools Y. Wang et al.
8. Open flux estimates in Saturn's magnetosphere during the January 2004 Cassini‐HST campaign, and implications for reconnection rates S. Badman et al.
9. ORIGIN OF ELECTRON CYCLOTRON MASER INDUCED RADIO EMISSIONS AT ULTRACOOL DWARFS: MAGNETOSPHERE-IONOSPHERE COUPLING CURRENTS J. Nichols et al.
10. Global response of the upper thermospheric winds to large ion drifts in the Jovian ovals T. Majeed et al.
11. Magnetosphere‐Ionosphere‐Thermosphere Coupling at Jupiter Using a Three‐Dimensional Atmospheric General Circulation Model J. Yates et al.
12. Whistler-mode waves with latitudinal variation drive by loss-cone beams and a parallel DC electric field in Jupiter’s magnetosphere . Ankita et al.
13. Magnetosphere-ionosphere coupling at Jupiter-like exoplanets with internal plasma sources: implications for detectability of auroral radio emissions J. Nichols
14. Auroral radio emission from ultracool dwarfs: a Jovian model S. Turnpenney et al.
15. Plasma measurements in the Jovian polar region with Juno/JADE J. Szalay et al.
16. A simple quantitative model of plasma flows and currents in Saturn's polar ionosphere S. Cowley et al.
17. Spatial Distribution of the Pedersen Conductance in the Jovian Aurora From Juno‐UVS Spectral Images J. Gérard et al.
18. A model of force balance in Jupiter's magnetodisc including hot plasma pressure anisotropy J. Nichols et al.
19. An Enhancement of Jupiter's Main Auroral Emission and Magnetospheric Currents J. Nichols et al.
20. Variability of Jupiter's Main Auroral Emission and Satellite Footprints Observed With HST During the Galileo Era M. Vogt et al.
21. Discontinuity in Jupiter's main auroral oval A. Radioti et al.
22. Auroral evidence of a localized magnetic anomaly in Jupiter's northern hemisphere D. Grodent et al.
23. Wave‐Particle Interaction of Alfvén Waves in Jupiter's Magnetosphere: Auroral and Magnetospheric Particle Acceleration J. Saur et al.
24. Solar Cycle Effects on the Dynamics of Jupiter’s and Saturn’s Magnetospheres C. Jackman & C. Arridge
25. Statistical characteristics of field-aligned currents in Saturn's nightside magnetosphere D. Talboys et al.
26. An Initial Study Into the Long‐Term Influence of Solar Wind Dynamic Pressure on Jupiter's Thermosphere J. Yates et al.
27. Response of the Jovian thermosphere to variations in solar EUV flux C. Tao et al.
28. Thirty years of H3+ astronomy S. Miller et al.
29. On the links between the radio flux and magnetodisk distortions at Jupiter P. Louarn et al.
30. Modeling of Jupiter's auroral curtain and upper atmospheric thermal structure I. Cohen & J. Clarke
31. Relation of Jupiter's Dawnside Main Emission Intensity to Magnetospheric Currents During the Juno Mission J. Nichols & S. Cowley
32. Solar wind-magnetosphere–ionosphere coupling at Jupiter E. Bunce et al.
33. Response of the Jovian thermosphere to a transient ‘pulse’ in solar wind pressure J. Yates et al.
34. A LOFAR mini-survey for low-frequency radio emission from the nearest brown dwarfs B. Burningham et al.
35. Effect of Meteoric Ions on Ionospheric Conductance at Jupiter Y. Nakamura et al.
36. Magnetosphere-ionosphere coupling in Jupiter's middle magnetosphere: Computations including a self-consistent current sheet magnetic field model J. Nichols
37. Mapping the electron energy in Jupiter's aurora: Hubble spectral observations J. Gérard et al.
38. Long‐Term Variability of Jupiter's Magnetodisk and Implications for the Aurora M. Vogt et al.
39. The color ratio-intensity relation in the Jovian aurora: Hubble observations of auroral components J. Gérard et al.
40. Response of Jupiter's UV auroras to interplanetary conditions as observed by the Hubble Space Telescope during the Cassini flyby campaign J. Nichols et al.
41. Saturn's auroral/polar H+3 infrared emission T. Stallard et al.
42. Local Time Asymmetries in Jupiter's Magnetodisc Currents C. Lorch et al.
43. Characterizing the limitations to the coupling between Saturn's ionosphere and middle magnetosphere L. Ray et al.
44. Sliding Contacts in Planetary Magnetospheres E. Belenkaya & I. Alexeev
45. Jovian magnetosphere–ionosphere current system characterized by diurnal variation of ionospheric conductance C. Tao et al.
46. Local time variations in Jupiter's magnetosphere‐ionosphere coupling system L. Ray et al.
47. The impact of an ICME on the Jovian X‐ray aurora W. Dunn et al.
48. Magnetosphere‐ionosphere coupling at Jupiter: Effect of field‐aligned potentials on angular momentum transport L. Ray et al.
49. Low-frequency monitoring of flare star binary CR Draconis: long-term electron-cyclotron maser emission J. Callingham et al.
50. Characteristics of Jovian morning bright FUV aurora from Hubble Space Telescope/Space Telescope Imaging Spectrograph imaging and spectral observations J. Gustin et al.
51. Jovian Auroral Radio Sources Detected In Situ by Juno/Waves: Comparisons With Model Auroral Ovals and Simultaneous HST FUV Images C. Louis et al.
52. Plasma mass loading from the extended neutral gas torus of Enceladus as inferred from the observed plasma corotation lag D. Pontius & T. Hill
53. Simulation of Dawn‐To‐Dusk Electric Field in the Jovian Inner Magnetosphere via Region 2‐Like Field‐Aligned Current Y. Nakamura et al.
54. Magnetospheric Science Objectives of the Juno Mission F. Bagenal et al.
55. Magnetosphere‐Ionosphere‐Thermosphere Coupling Study at Jupiter Based on Juno's First 30 Orbits and Modeling Tools S. Al Saati et al.
56. Transient small‐scale structure in the main auroral emission at Jupiter B. Palmaerts et al.
57. Jovian Auroral Electron Precipitation Budget—A Statistical Analysis of Diffuse, Mono‐Energetic, and Broadband Auroral Electron Distributions A. Salveter et al.
58. Callisto in the Magnetosphere of Jupiter E. Belenkaya
59. Generation of parallel electric fields in the Jupiter–Io torus wake region R. Ergun et al.
60. A Brief Review of Ultraviolet Auroral Emissions on Giant Planets D. Grodent
61. Global Simulation of the Jovian Magnetosphere: Transitional Structure From the Io Plasma Disk to the Plasma Sheet T. Tanaka et al.
62. Global MHD simulations of the Response of Jupiter's Magnetosphere and Ionosphere to Changes in the Solar Wind and IMF Y. Sarkango et al.
63. Neutral wind control of the Jovian magnetosphere‐ionosphere current system C. Tao et al.
64. The Pedersen and Hall conductances in the Jovian polar regions: New maps based on a broadband electron energy distribution G. Sicorello et al.
65. Processes of auroral thermal structure at Jupiter: Analysis of multispectral temperature observations with the Jupiter Thermosphere General Circulation Model T. Majeed et al.
66. Precipitating Electron Energy Flux and Characteristic Energies in Jupiter's Main Auroral Region as Measured by Juno/JEDI G. Clark et al.
67. Jupiter's Low‐Altitude Auroral Zones: Fields, Particles, Plasma Waves, and Density Depletions A. Sulaiman et al.
68. Magnetosphere‐ionosphere coupling at Jupiter: A parameter space study L. Ray et al.
69. Auroral evidence of radial transport at Jupiter during January 2014 R. Gray et al.
70. Oscillation of Saturn's southern auroral oval J. Nichols et al.
71. Magnetosphere‐ionosphere coupling at Jupiter: Expectations for Juno Perijove 1 from a steady state axisymmetric physical model S. Cowley et al.
72. Solar Wind and Internally Driven Dynamics: Influences on Magnetodiscs and Auroral Responses P. Delamere et al.
73. Morphology of the Auroral Tail of Io, Europa, and Ganymede From JIRAM L‐Band Imager A. Moirano et al.
74. Modelling magnetic fields and plasma flows in the magnetosphere of Jupiter D. Millas et al.
75. Io‐Jupiter interaction: Alfvén wave propagation and ionospheric Alfvén resonator Y. Su et al.
76. 1. Transport of Mass, Momentum and Energy in Planetary Magnetodisc Regions N. Achilleos et al.
77. On the nature and location of the proposed twin vortex systems in Saturn's polar upper atmosphere C. Smith
78. Variation of different components of Jupiter's auroral emission J. Nichols et al.
79. Variability and Hemispheric Symmetry of the Pedersen Conductance in the Jovian Aurora J. Gérard et al.
80. Interplanetary magnetic field at ∼9 AU during the declining phase of the solar cycle and its implications for Saturn's magnetospheric dynamics C. Jackman et al.
81. A simple axisymmetric model of magnetosphere‐ionosphere coupling currents in Jupiter's polar ionosphere S. Cowley et al.
82. Synchronized oscillations in energetic electron fluxes and whistler wave intensity in Jupiter's middle magnetosphere P. Bespalov et al.
83. Auroral Processes at the Giant Planets: Energy Deposition, Emission Mechanisms, Morphology and Spectra S. Badman et al.
84. Energy‐flux relationship in the FUV Jovian aurora deduced from HST‐STIS spectral observations J. Gustin et al.
85. Response of the Jovian Magnetosphere‐Ionosphere System to the Interplanetary Magnetic Field Discontinuity: A Simulation Study Y. Wang et al.