52 citations as recorded by crossref.

1. An Observation Linking the Origin of Plasmaspheric Hiss to Discrete Chorus Emissions J. Bortnik et al.
2. Observational evidence of the generation mechanism for rising-tone chorus C. Cully et al.
3. Multipoint observations of plasma phenomena made in space by Cluster M. Goldstein et al.
4. Observation of chorus waves by the Van Allen Probes: Dependence on solar wind parameters and scale size H. Aryan et al.
5. Nonlinear damping of chorus emissions at local half cyclotron frequencies observed by Geotail at L > 9 T. Habagishi et al.
6. Simultaneous satellite observations of VLF chorus, hot and relativistic electrons in a magnetic storm “recovery” phase Y. Kasahara et al.
7. Multievent Study of Characteristics and Propagation of Naturally Occurring ELF/VLF Waves Using High‐Latitude Ground Observations and Conjunctions With the Arase Satellite C. Martinez‐Calderon et al.
8. Wave‐particle interactions in the equatorial source region of whistler‐mode emissions O. Santolík et al.
9. Diurnal dependence of ELF/VLF hiss and its relation to chorus at L = 2.4 D. Golden et al.
10. Statistics of Unusual Naturally Occurring VLF Radio Emissions Termed Bursty‐Patches Observed at Kannuslehto, Finland C. Martinez‐Calderon et al.
11. Wave Polarization Analyzed by Singular Value Decomposition of the Spectral Matrix in the Presence of Noise U. Taubenschuss & O. Santolík
12. Plasmaspheric Hiss: Coherent and Intense B. Tsurutani et al.
13. Resonance zones for electron interaction with plasma waves in the Earth’s dipole magnetosphere. I. Evaluation for field-aligned chorus, hiss, and electromagnetic ion cyclotron waves B. Ni & D. Summers
14. Role of the plasmapause in dictating the ground accessibility of ELF/VLF chorus D. Golden et al.
15. Studies on different geophysical and extra-terrestrial events within the Earth-ionosphere cavity in terms of ULF/ELF/VLF radio waves M. Sanfui et al.
16. Location and size of the global source region of whistler mode chorus M. Hayosh et al.
17. Whistler mode wave generation at the edges of a magnetic dip Z. Zhima et al.
18. Thunderstorms, Lightning, Sprites and Magnetospheric Whistler-Mode Radio Waves D. Siingh et al.
19. A linear theory of the backward-wave-oscillator regime in the magnetospheric cyclotron ELF/VLF maser A. Bespalov & A. Demekhov
20. Restrictions on the quasi-linear description of electron–chorus interaction in the earth's magnetosphere G. Khazanov & D. Sibeck
21. Electron hybrid code simulation of whistler-mode chorus generation with real parameters in the Earth’s inner magnetosphere Y. Katoh & Y. Omura
22. Characteristics of discrete VLF falling-tone chorus emissions observed at low latitude ground station Jammu A. Singh et al.
23. Source of the Bursty Bulk Flow Diffuse Aurora: Electrostatic Cyclotron Harmonic and Whistler Waves in the Coupling of Bursty Bulk Flows to Auroral Precipitation D. Wendel et al.
24. Triggering process of whistler mode chorus emissions in the magnetosphere Y. Omura & D. Nunn
25. Chorus and chorus‐like emissions seen by the ionospheric satellite DEMETER M. Parrot et al.
26. Electron loss and acceleration during storm time: The contribution of wave-particle interaction, radial diffusion, and transport processes H. Fu et al.
27. A review of unusual VLF bursty-patches observed in Northern Finland for Earth, Planets and Space C. Martinez-Calderon et al.
28. Global Map of Chorus Wave Sizes in the Inner Magnetosphere H. Aryan et al.
29. DEMETER observations of high-latitude chorus waves penetrating the plasmasphere during a geomagnetic storm Z. Zhima et al.
30. Theories of Growth and Propagation of Parallel Whistler-Mode Chorus Emissions: A Review M. Hanzelka & O. Santolík
31. A generation mechanism of chorus emissions using BWO theory A. Singh et al.
32. On the numerical modelling of VLF chorus dynamical spectra D. Nunn et al.
33. Survey of Poynting flux of whistler mode chorus in the outer zone O. Santolík et al.
34. Pitch angle transport of electrons due to cyclotron interactions with the coherent chorus subelements G. Lakhina et al.
35. Whistler-mode chorus emissions observed at Nanital (L= 1.16)
36. Measurability of the Nonlinear Response of Electron Distribution Function to Chorus Emissions in the Earth's Radiation Belt M. Hanzelka et al.
37. Properties of obliquely propagating chorus O. Verkhoglyadova et al.
38. Can One Hear Whistler Waves? C. Cheverry
39. Chorus wave amplification: A free electron laser in the Earth’s magnetosphere A. Soto-Chavez et al.
40. Simultaneous Generation of EMIC and MS Waves During the Magnetic Dip in the Inner Magnetosphere Z. Huang et al.
41. MAVEN Observations of Whistler-mode Waves Within the Magnetic Dips in the Martian Ionopause/Ionosphere J. Wang et al.
42. A model for falling-tone chorus A. Soto-Chavez et al.
43. An explanation of the observation of whistler-mode chorus emissions at the Indian Antarctic station, Maitri (L=4.5) A. Singh et al.
44. The Structure and Microstructure of Rising‐Tone Chorus With Frequencies Crossing at f ∼ 0.5 fce R. Chen et al.
45. Observation of a unique storm-time VLF chorus emissions at low latitude Indian ground station Jammu ( L = 1.17 $L=1.17$ ) K. Singh
46. On the occurrence of ground observations of ELF/VLF magnetospheric amplification induced by the HAARP facility M. Gołkowski et al.
47. Nonlinear mechanisms of lower‐band and upper‐band VLF chorus emissions in the magnetosphere Y. Omura et al.
48. Two sources of dayside intense, quasi‐coherent plasmaspheric hiss: A new mechanism for the slot region? B. Falkowski et al.
49. Relativistic electron acceleration during HILDCAA events: are precursor CIR magnetic storms important? R. Hajra et al.
50. The role of electrons during chorus intensification: Energy source and energy loss H. Fu et al.
51. The Effects of Localized Thermal Pressure on Equilibrium Magnetic Fields and Particle Drifts in The Inner Magnetosphere Z. Xia et al.
52. The Electric and Magnetic Fields Instrument Suite and Integrated Science (EMFISIS): Science, Data, and Usage Best Practices C. Kletzing et al.