63 citations as recorded by crossref.

1. Discovery of very large amplitude whistler‐mode waves in Earth's radiation belts C. Cattell et al.
2. Temporal evolution of substorm‐enhanced whistler‐mode waves: Relationship between space‐based observations, ground‐based observations, and energetic electrons G. Abel et al.
3. DEMETER observations of high-latitude chorus waves penetrating the plasmasphere during a geomagnetic storm Z. Zhima et al.
4. Role of geomagnetic disturbance on whistler occurrence at a low latitude station S. Singh et al.
5. Particle simulations of whistler‐mode rising‐tone emissions triggered by waves with different amplitudes M. Hikishima & Y. Omura
6. Theory and simulation of the generation of whistler‐mode chorus Y. Omura et al.
7. Central position of the source region of storm-time chorus O. Santolík et al.
8. Properties of dayside outer zone chorus during HILDCAA events: Loss of energetic electrons B. Tsurutani et al.
9. New observations of electromagnetic harmonic ELF emissions in the ionosphere by the DEMETER satellite during large magnetic storms M. Parrot et al.
10. On the Importance of Using Event‐Specific Wave Diffusion Rates in Modeling Diffuse Electron Precipitation Y. Yu et al.
11. Chorus source properties that produce time shifts and frequency range differences observed on different Cluster spacecraft J. Chum et al.
12. Nonlinear Evolution of Counter‐Propagating Whistler Mode Waves Excited by Anisotropic Electrons Within the Equatorial Source Region: 1‐D PIC Simulations H. Chen et al.
13. Current problems in studies of magnetospheric cyclotron masers and new space project “resonance” A. Demekhov et al.
14. Generation of VLF emissions with the increasing and decreasing frequency in the magnetosperic cyclotron maser in the backward wave oscillator regime A. Demekhov
15. Whistler mode wave growth and propagation in the prenoon magnetosphere C. Watt et al.
16. Spatio‐temporal structure of storm‐time chorus O. Santolík et al.
17. Examples of unusual ionospheric observations made by the DEMETER satellite over seismic regions M. Parrot et al.
18. Multispacecraft observations of chorus dispersion and source location A. Breneman et al.
19. Wave normal angles of magnetospheric chorus emissions observed on the Polar spacecraft N. Haque et al.
20. Formation of VLF chorus frequency spectrum: Cluster data and comparison with the backward wave oscillator model V. Trakhtengerts et al.
21. Source location of falling tone chorus S. Kurita et al.
22. Interpretation of Cluster data on chorus emissions using the backward wave oscillator model V. Trakhtengerts et al.
23. Wave normal angles of whistler mode chorus rising and falling tones U. Taubenschuss et al.
24. Study of relativistic beam of electron on whistler mode waves for subtracted distribution in Saturnian magnetosphere K. Shukla et al.
25. Analysis of plasma waves observed within local plasma injections seen in Saturn's magnetosphere J. Menietti et al.
26. Chorus observations by the Polar spacecraft near the mid-altitude cusp J. Menietti et al.
27. Specific features of VLF wave propagation in the earth’s inner magnetosphere D. Mendzhul et al.
28. The Electric and Magnetic Fields Instrument Suite and Integrated Science (EMFISIS): Science, Data, and Usage Best Practices C. Kletzing et al.
29. Chorus whistler wave source scales as determined from multipoint Van Allen Probe measurements O. Agapitov et al.
30. Propagation of whistler mode chorus to low altitudes: Spacecraft observations of structured ELF hiss O. Santolík et al.
31. THEMIS analysis of observed equatorial electron distributions responsible for the chorus excitation W. Li et al.
32. Excitation of Highly Oblique Lower Band and Upper Band Chorus by a Loss Cone Feature and Temperature Anisotropy Distribution Q. Zhou et al.
33. Butterfly Distribution of Relativistic Electrons Driven by Parallel Propagating Lower Band Whistler Chorus Waves S. Saito & Y. Miyoshi
34. Backward wave oscillator regime of the whistler cyclotron instability in an inhomogeneous magnetic field A. Demekhov et al.
35. The dual role of ELF/VLF chorus waves in the acceleration and precipitation of radiation belt electrons J. Bortnik & R. Thorne
36. Multispacecraft observations of chorus emissions as a tool for the plasma density fluctuations' remote sensing O. Agapitov et al.
37. Observations of chorus at Saturn using the Cassini Radio and Plasma Wave Science instrument G. Hospodarsky et al.
38. A statistical study of the spatial distribution and source-region size of chorus waves using Van Allen Probes data S. Teng et al.
39. Dynamics of the magnetospheric cyclotron ELF/VLF maser in the backward-wave-oscillator regime. II. The influence of the magnetic-field inhomogeneity A. Demekhov & V. Trakhtengerts †
40. Chorus Wave Properties From Van Allen Probes: Quantifying the Impact of the Sheath Corrected Electric Field D. Hartley et al.
41. 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.
42. Poynting vector and wave vector directions of equatorial chorus U. Taubenschuss et al.
43. Oblique propagation of whistler mode waves in the chorus source region O. Santolík et al.
44. Analysis methods for multi-component wave measurements on board the DEMETER spacecraft O. Santolík et al.
45. Propagation of lower‐band whistler‐mode waves in the outer Van Allen belt: Systematic analysis of 11 years of multi‐component data from the Cluster spacecraft O. Santolík et al.
46. Oblique Whistler-Mode Waves in the Earth’s Inner Magnetosphere: Energy Distribution, Origins, and Role in Radiation Belt Dynamics A. Artemyev et al.
47. Observations of the Source Region of Whistler Mode Waves in Magnetosheath Mirror Structures N. Kitamura et al.
48. Storm time, short‐lived bursts of relativistic electron precipitation detected by subionospheric radio wave propagation C. Rodger et al.
49. Full Particle Simulation of Whistler‐Mode Triggered Falling‐Tone Emissions in the Magnetosphere T. Nogi et al.
50. Relativistic turning acceleration of radiation belt electrons by whistler mode chorus N. Furuya et al.
51. The mid-high latitude whistler mode chorus waves observed around substorm onsets J. Yang et al.
52. A Three-Dimensional Ray Tracing Study on Whistler-Mode Chorus During Geomagnetic Activities Q. Zhou et al.
53. Wave emissions at half electron gyroharmonics in the equatorial plasmasphere region: CLUSTER observations and statistics F. El-Lemdani Mazouz et al.
54. Thunderstorms, Lightning, Sprites and Magnetospheric Whistler-Mode Radio Waves D. Siingh et al.
55. Immediate Impact of Solar Wind Dynamic Pressure Pulses on Whistler‐Mode Chorus Waves in the Inner Magnetosphere Y. Jin et al.
56. Modeling the wave power distribution and characteristics of plasmaspheric hiss J. Bortnik et al.
57. Location and size of the global source region of whistler mode chorus M. Hayosh et al.
58. Advances in Plasmaspheric Wave Research with CLUSTER and IMAGE Observations A. Masson et al.
59. Landau damping and resultant unidirectional propagation of chorus waves J. Bortnik et al.
60. Survey of Poynting flux of whistler mode chorus in the outer zone O. Santolík et al.
61. A microscopic and nanoscopic view of storm‐time chorus on 31 March 2001 O. Santolík et al.
62. A statistical study of the propagation characteristics of whistler waves observed by Cluster O. Agapitov et al.
63. Chorus and chorus‐like emissions seen by the ionospheric satellite DEMETER M. Parrot et al.