91 citations as recorded by crossref.

1. Properties and drivers of fast interplanetary shocks near the orbit of the Earth (1995–2013) E. Kilpua et al.
2. Magnetospheric modes and solar wind energy coupling efficiency T. Pulkkinen et al.
3. The Need for Near-Earth Multi-Spacecraft Heliospheric Measurements and an Explorer Mission to Investigate Interplanetary Structures and Transients in the Near-Earth Heliosphere N. Lugaz et al.
4. Multipoint Observations of the Dynamics at an ICME Sheath–Ejecta Boundary M. Ala-Lahti et al.
5. Solar and interplanetary sources of major geomagnetic storms (Dst ≤ −100 nT) during 1996–2005 J. Zhang et al.
6. Solar wind‐magnetosphere coupling efficiency during ejecta and sheath‐driven geomagnetic storms M. Myllys et al.
7. Achievements and Challenges in the Science of Space Weather H. Koskinen et al.
8. CIR versus CME drivers of the ring current during intense magnetic storms M. Liemohn et al.
9. Geoeffective Properties of Solar Transients and Stream Interaction Regions E. Kilpua et al.
10. Dynamics of large‐scale solar wind streams obtained by the double superposed epoch analysis Y. Yermolaev et al.
11. Interplanetary Shock Candidates Observed at Venus’s Orbit C. Wang et al.
12. Geomagnetic Activity Following Interplanetary Shocks in Solar Cycles 23 and 24 E. Echer et al.
13. Transmission of an ICME Sheath Into the Earth's Magnetosheath and the Occurrence of Traveling Foreshocks M. Ala‐Lahti et al.
14. Halo coronal mass ejections during Solar Cycle 24: reconstruction of the global scenario and geoeffectiveness C. Scolini et al.
15. On the identification of the spatiotemporal locations of solar wind structures during an intense geomagnetic storm V. Chukwuma et al.
16. Interplanetary Sheaths and Corotating Interaction Regions: A Comparative Statistical Study on Their Characteristics and Geoeffectiveness R. Hajra et al.
17. Acceleration of an interplanetary shock through the magnetosheath: a global hybrid simulation C. Moissard et al.
18. Statistical investigation of heliospheric conditions resulting in magnetic storms Y. Yermolaev et al.
19. Detailed understanding of reduced geoeffectiveness of solar cycle 24 in association with geomagnetic storms R. Selvakumaran et al.
20. Superposed epoch analyses of HILDCAAs and their interplanetary drivers: Solar cycle and seasonal dependences R. Hajra et al.
21. Geoeffectivity of Coronal Mass Ejections H. Koskinen & K. Huttunen
22. Dynamics of Large-Scale Solar-Wind Streams Obtained by the Double Superposed Epoch Analysis: 2. Comparisons of CIRs vs. Sheaths and MCs vs. Ejecta Y. Yermolaev et al.
23. Near-Earth Interplanetary Coronal Mass Ejections and Their Association with DH Type II Radio Bursts During Solar Cycles 23 and 24 B. Patel et al.
24. Relationship between the Parameters of Various Solar Wind Types and Geomagnetic Activity Indices L. Dremukhina et al.
25. Space weather investigation Frontier (SWIFT) M. Akhavan-Tafti et al.
26. Some problems of identifying types of large-scale solar wind and their role in the physics of the magnetosphere Y. Yermolaev et al.
27. On global relative geo-effectiveness of solar wind structures during an intense geomagnetic storm: A case study of an intense geomagnetic storm driven by sandwich-structured CME V. Chukwuma et al.
28. Coexistence of a planar magnetic structure and an Alfvén wave in the shock-sheath of an interplanetary coronal mass ejection Z. Shaikh et al.
29. The effects of expansion and turbulence on the interplanetary evolution of a magnetic cloud M. Sangalli et al.
30. Near-earth solar wind flows and related geomagnetic activity during more than four solar cycles (1963–2011) I. Richardson & H. Cane
31. Statistical study of interplanetary condition effect on geomagnetic storms Y. Yermolaev et al.
32. Quasi-planar ICME sheath: A cause of the first two-step extreme geomagnetic storm of the 25th solar cycle observed on 23 April 2023 K. Ghag et al.
33. Planar Magnetic Structures Downstream of Coronal Mass Ejection–driven Shocks in the Inner Heliosphere M. Ruan et al.
34. Solar and interplanetary sources of geomagnetic storms: Space weather aspects Y. Yermolaev & M. Yermolaev
35. Planar magnetic structures in coronal mass ejection-driven sheath regions E. Palmerio et al.
36. Sub-daily solar wind-magnetosphere energy transfer during major geomagnetic storms of solar cycle 23 R. Anoke-Uzosike et al.
37. Coronal Magnetic Structure of Earthbound CMEs and In Situ Comparison E. Palmerio et al.
38. Interplanetary Shock Parameters Near Jupiter's Orbit E. Echer
39. Energy transfer during intense geomagnetic storms driven by interplanetary coronal mass ejections and their sheath regions J. Guo et al.
40. Probing Coronal Mass Ejection Inclination Effects with EUHFORIA K. Martinić et al.
41. Predicting the magnetic vectors within coronal mass ejections arriving at Earth: 1. Initial architecture N. Savani et al.
42. Why have geomagnetic storms been so weak during the recent solar minimum and the rising phase of cycle 24? E. Kilpua et al.
43. Proton Temperature Anisotropy within the Interplanetary Coronal Mass Ejections Sheath at 1 au Z. Shaikh et al.
44. A statistical comparison of solar wind sources of moderate and intense geomagnetic storms at solar minimum and maximum J. Zhang et al.
45. Concurrent effect of Alfvén waves and planar magnetic structure on geomagnetic storms Z. Shaikh et al.
46. Predictability of variable solar–terrestrial coupling I. Daglis et al.
47. Solar Wind Properties and Geospace Impact of Coronal Mass Ejection‐Driven Sheath Regions: Variation and Driver Dependence E. Kilpua et al.
48. Multipoint Study of Successive Coronal Mass Ejections Driving Moderate Disturbances at 1 au E. Palmerio et al.
49. Ring current simulations of the 90 intense storms during solar cycle 23 M. Liemohn & M. Jazowski
50. Structure and fluctuations of a slow ICME sheath observed at 0.5 au by the Parker Solar Probe E. Kilpua et al.
51. Interplanetary drivers of ionospheric prompt penetration electric fields J. Guo et al.
52. Influence of epoch time selection on the results of superposed epoch analysis using ACE and MPA data R. Ilie et al.
53. Understanding the variability of magnetic storms caused by ICMEs R. Benacquista et al.
54. Spatial Coherence of Interplanetary Coronal Mass Ejection Sheaths at 1 AU M. Ala‐Lahti et al.
55. Statistical Analysis of Magnetic Field Fluctuations in Coronal Mass Ejection-Driven Sheath Regions E. Kilpua et al.
56. Solar wind parameters and geomagnetic indices for four different interplanetary shock/ICME structures C. Yue & Q. Zong
57. Magnetospheric cross-field currents during the January 6–7, 2011 high-speed stream-driven interval M. Liemohn et al.
58. Unraveling the drivers of the storm time radiation belt response E. Kilpua et al.
59. Properties of the Sheath Regions of Coronal Mass Ejections with or without Shocks from STEREO in situ Observations near 1 au T. Salman et al.
60. A Study of Fluctuations in Magnetic Cloud‐Driven Sheaths C. Moissard et al.
61. Flux enhancement of radiation belt electrons during geomagnetic storms driven by coronal mass ejections and corotating interaction regions R. Kataoka & Y. Miyoshi
62. Relative occurrence rate and geoeffectiveness of large-scale types of the solar wind Y. Yermolaev et al.
63. Geoeffectiveness (Dst and Kp) of interplanetary coronal mass ejections during 1995–2009 and implications for storm forecasting I. Richardson & H. Cane
64. Statistic study of the geoeffectiveness of compression regions CIRs and Sheaths Y. Yermolaev et al.
65. Magnetic field and dynamic pressure ULF fluctuations in coronal-mass-ejection-driven sheath regions E. Kilpua et al.
66. Coronal mass ejections and their sheath regions in interplanetary space E. Kilpua et al.
67. Depleting effects of ICME-driven sheath regions on the outer electron radiation belt H. Hietala et al.
68. Asymmetric development of magnetospheric storms during magnetic clouds and sheath regions K. Huttunen et al.
69. Modeling the time behavior of the D st index during the main phase of magnetic storms generated by various types of solar wind N. Nikolaeva et al.
70. Peculiarities of long-wave radio bursts from solar flares preceding strong geomagnetic storms V. Prokudina et al.
71. Effects of Geometries and Substructures of ICMEs on Geomagnetic Storms J. Lee et al.
72. Impact of ICME sheath planarity on Earth’s outer radiation belt K. Ghag et al.
73. Magnetic cloud boundary layer of 9 November 2004 and its associated space weather effects P. Zuo et al.
74. Spatial Distribution of Electromagnetic Waves near the Proton Cyclotron Frequency in ICME Sheath Regions Associated with Quasi-perpendicular Shocks: Wind Observations Q. Li et al.
75. Effect of the solar wind density on the evolution of normal and inverse coronal mass ejections S. Hosteaux et al.
76. Space Weather: Physics, Effects and Predictability A. Singh et al.
77. Ionospheric response to the initial phase of geomagnetic storms: Common features W. Wang et al.
78. Indian solar and heliospheric physics vision: Fundamental science to a space weather resilient society D. Nandy et al.
79. Statistical analysis of mirror mode waves in sheath regions driven by interplanetary coronal mass ejection M. Ala-Lahti et al.
80. Magnetic field fluctuation properties of coronal mass ejection-driven sheath regions in the near-Earth solar wind E. Kilpua et al.
81. Statistical storm time examination of MLT‐dependent plasmapause location derived from IMAGE EUV R. Katus et al.
82. GUMICS-4 analysis of interplanetary coronal mass ejection impact on Earth during low and typical Mach number solar winds A. Lakka et al.
83. Statistical Study of Geo-Effectiveness of Planar Magnetic Structures Evolved within ICME’s K. Ghag et al.
84. Solar wind drivers of large geomagnetically induced currents during the solar cycle 23 K. Huttunen et al.
85. Predicting the magnetic vectors within coronal mass ejections arriving at Earth: 2. Geomagnetic response N. Savani et al.
86. STATISTICAL STUDY OF STRONG AND EXTREME GEOMAGNETIC DISTURBANCES AND SOLAR CYCLE CHARACTERISTICS E. Kilpua et al.
87. What Solar–Terrestrial Link Researchers Should Know about Interplanetary Drivers Y. Yermolaev et al.
88. Assessing the Geoeffectiveness of Stream Interaction Regions through Physically Interpretable Machine Learning Y. Ye et al.
89. Thermospheric nitric oxide response to shock‐led storms D. Knipp et al.
90. The Ionospheric Impact of an ICME‐Driven Sheath Region Over Indian and American Sectors in the Absence of a Typical Geomagnetic Storm D. Rout et al.
91. Dependence of geomagnetic activity during magnetic storms on the solar wind parameters for different types of streams N. Nikolaeva et al.