522 citations as recorded by crossref.

1. Orientations of LASCO Halo CMEs and their connection to the flux rope structure of interplanetary CMEs V. Yurchyshyn et al.
2. Multi-point analysis of coronal mass ejection flux ropes using combined data from Solar Orbiter, BepiColombo, and Wind A. Weiss et al.
3. Multipoint ICME encounters: Pre-STEREO and STEREO observations E. Kilpua et al.
4. On the origins and timescales of geoeffective IMF M. Lockwood et al.
5. Sizes and relative geoeffectiveness of interplanetary coronal mass ejections and the preceding shock sheaths during intense storms in 1996–2005 J. Zhang et al.
6. Geomagnetic response of interplanetary coronal mass ejections in the Earth's magnetosphere . Badruddin et al.
7. Inferring interplanetary flux rope orientation with the minimum residue method H. Li et al.
8. The Effect of Magnetic Field Line Topology on ICME-related GCR Modulation E. Davies et al.
9. Identification of Solar Sources of Major Geomagnetic Storms between 1996 and 2000 J. Zhang et al.
10. Solar Imprint on ICMEs, Their Magnetic Connectivity, and Heliospheric Evolution N. Crooker & T. Horbury
11. Forbush decreases and turbulence levels at coronal mass ejection fronts P. Subramanian et al.
12. Challenges in Forecasting the Evolution of a Distorted CME Observed During the First Close Solar Orbiter Perihelion A. Liberatore et al.
13. Interplanetary coronal mass ejections during the descending cycle 23: Sheath and ejecta properties comparison E. Mitsakou et al.
14. MHD modelling of the near-sun evolution of coronal mass ejection initiated from a sheared arcade J. Cai et al.
15. A kinematically distorted flux rope model for magnetic clouds M. Owens et al.
16. Relationship between solar wind low‐energy energetic ion enhancements and large geomagnetic storms Z. Smith et al.
17. Analysis of Recovery Phase Characteristics for Different ICME Polarities (1995–2015) W. Alotaibi et al.
18. Investigating Coronal Mass Ejections through Multispacecraft Measurements: STEREO-A and L1 in 2022–2023 S. Banu et al.
19. The life of a CME and the development of a MIR: From the Sun to 58 AU J. Richardson et al.
20. Relating white light and in situ observations of coronal mass ejections: A review A. Rouillard
21. Physics of interplanetary magnetic flux ropes: Toward prediction of geomagnetic storms K. Marubashi
22. VARIATIONS OF THE MUON FLUX AT SEA LEVEL ASSOCIATED WITH INTERPLANETARY ICMEs AND COROTATING INTERACTION REGIONS C. Augusto et al.
23. Near-Sun and 1 AU magnetic field of coronal mass ejections: a parametric study S. Patsourakos & M. Georgoulis
24. An Observationally Constrained Analytical Model for Predicting the Magnetic Field Vectors of Interplanetary Coronal Mass Ejections at 1 au R. Sarkar et al.
25. The basic characteristics of EUV post-eruptive arcades and their role as tracers of coronal mass ejection source regions D. Tripathi et al.
26. Isolated magnetic field structures in Mercury's magnetosheath as possible analogues for terrestrial magnetosheath plasmoids and jets T. Karlsson et al.
27. Unusual Plasma and Particle Signatures at Mars and STEREO-A Related to CME–CME Interaction M. Dumbović et al.
28. Kinematic Treatment of Coronal Mass Ejection Evolution in the Solar Wind P. Riley & N. Crooker
29. Evolution of Interplanetary Coronal Mass Ejection Complexity: A Numerical Study through a Swarm of Simulated Spacecraft C. Scolini et al.
30. Advances in 3D Reconstruction of Coronal Mass Ejections Z. Xing-mei et al.
31. Observation-based modelling of magnetised coronal mass ejections with EUHFORIA C. Scolini et al.
32. Internal structure of magnetic clouds: Plasma and composition B. Lynch et al.
33. Intercomparison of NEAR and Wind interplanetary coronal mass ejection observations T. Mulligan et al.
34. The Automatic Predictability of Super Geomagnetic Storms from halo CMEs associated with Large Solar Flares H. Song et al.
35. Observable Properties of the Breakout Model for Coronal Mass Ejections B. Lynch et al.
36. PLASMA AND MAGNETIC FIELD CHARACTERISTICS OF SOLAR CORONAL MASS EJECTIONS IN RELATION TO GEOMAGNETIC STORM INTENSITY AND VARIABILITY Y. Liu et al.
37. Observations of the field-aligned residual flow inside magnetic cloud structure H. Li et al.
38. Importance of CME Radial Expansion on the Ability of Slow CMEs to Drive Shocks N. Lugaz et al.
39. Dynamical evolution of a magnetic cloud from the Sun to 5.4 AU M. Nakwacki et al.
40. Drag-Based Model (DBM) Tools for Forecast of Coronal Mass Ejection Arrival Time and Speed M. Dumbović et al.
41. Formation of Coronal Mass Ejections in the Solar Corona and Propagation of the Resulting Plasma Streams in the Heliosphere V. Slemzin et al.
42. On the relationship between magnetic cloud field polarity and geoeffectiveness E. Kilpua et al.
43. Modeling variations in CR density in magnetic clouds A. Belov et al.
44. A non‐force‐free approach to the topology of magnetic clouds in the solar wind M. Hidalgo et al.
45. Coronal mass ejections associated with interplanetary ejecta S. Bravo
46. Large scale MHD properties of interplanetary magnetic clouds S. Dasso et al.
47. Magnetic coupling of the Sun–Earth system – The view from STEREO S. Matthews & J. Culhane
48. A STEREO Survey of Magnetic Cloud Coronal Mass Ejections Observed at Earth in 2008–2012 B. Wood et al.
49. Models of Solar Wind Structures and Their Interaction with the Earth’s Space Environment J. Watermann et al.
50. Theoretical modeling for the stereo mission M. Aschwanden et al.
51. The Effect of Stream Interaction Regions on ICME Structures Observed in Longitudinal Conjunction R. Winslow et al.
52. Observations of a Small Interplanetary Magnetic Flux Rope Opening by Interchange Reconnection J. Wang et al.
53. A statistical study of magnetic cloud parameters and geoeffectiveness E. Echer et al.
54. Cosmic noise absorption signature of particle precipitation during interplanetary coronal mass ejection sheaths and ejecta E. Kilpua et al.
55. A statistical study of the geoeffectiveness of magnetic clouds during high solar activity years J. Zhang et al.
56. Recent progress on understanding coronal mass ejection/flare onset by a NASA living with a star focused science team M. Linton et al.
57. Solar and Heliospheric Causes of Geomagnetic Perturbations during the Growth Phase of Solar Cycle 23 V. Bothmer et al.
58. Coronal Mass Ejection (CME) Activity of Low Mass M Stars as An Important Factor for The Habitability of Terrestrial Exoplanets. I. CME Impact on Expected Magnetospheres of Earth-Like Exoplanets in Close-In Habitable Zones M. Khodachenko et al.
59. Energetic-particle-flux decreases related to magnetic cloud passages as observed by the Helios 1 and 2 spacecraft J. Blanco et al.
60. MULTI-POINT SHOCK AND FLUX ROPE ANALYSIS OF MULTIPLE INTERPLANETARY CORONAL MASS EJECTIONS AROUND 2010 AUGUST 1 IN THE INNER HELIOSPHERE C. Möstl et al.
61. Two examples of magnetic clouds with double rotations observed by the Ulysses spacecraft A. Rees & R. Forsyth
62. Interplanetary magnetic clouds: Statistical patterns and radial variations T. Mulligan et al.
63. Synthetic Remote-sensing and In Situ Observations of Fine-scale Structure in a Pseudostreamer Coronal Mass Ejection through the Solar Corona B. Lynch et al.
64. Forecasting the Structure and Orientation of Earthbound Coronal Mass Ejections E. Kilpua et al.
65. Effect of orientation of the solar wind magnetic clouds on the seasonal variation of geomagnetic activity N. Barkhatov et al.
66. How Magnetic Erosion Affects the Drag-Based Kinematics of Fast Coronal Mass Ejections S. Stamkos et al.
67. 2019 International Women’s Day event M. Dumbović et al.
68. Dependence of geomagnetic disturbances on extreme values of the solar wind E y component S. Kershengolts et al.
69. Magnetic reconnection exhausts at the boundaries of small interplanetary magnetic flux ropes H. Feng et al.
70. Near-Earth Interplanetary Coronal Mass Ejections During Solar Cycle 23 (1996 – 2009): Catalog and Summary of Properties I. Richardson & H. Cane
71. Distorted Magnetic Flux Ropes within Interplanetary Coronal Mass Ejections A. Weiss et al.
72. AN EMPIRICAL RECONSTRUCTION OF THE 2008 APRIL 26 CORONAL MASS EJECTION B. Wood & R. Howard
73. Forward Modeling of Coronal Mass Ejection Flux Ropes in the Inner Heliosphere with 3DCORE C. Möstl et al.
74. Interplanetary Coronal Mass Ejections from MAVEN Orbital Observations at Mars D. Zhao et al.
75. Effects of interplanetary magnetic clouds, interaction regions, and high‐speed streams on the transient modulation of galactic cosmic rays Y. Singh & . Badruddin
76. Analysis of large scale MHD quantities in expanding magnetic clouds M. Nakwacki et al.
77. Outer Van Allen belt trapped and precipitating electron flux responses to two interplanetary magnetic clouds of opposite polarity H. George et al.
78. Helicity and the solar dynamo N. Seehafer et al.
79. A model for stealth coronal mass ejections B. Lynch et al.
80. Characterization of the Complex Ejecta Measured In Situ on 19 – 22 March 2001 by Six Different Methods A. Ojeda-González et al.
81. Magnetic clouds in the solar wind: a numerical assessment of analytical models G. Dalakishvili et al.
82. Validation of EUHFORIA cone and spheromak coronal mass ejection models L. Rodriguez et al.
83. Properties of structured coronal mass ejections in solar cycle 23 H. Cremades et al.
84. Statistical Relationship Between Interplanetary Magnetic Field Conditions and the Helicity Sign of Flux Transfer Event Flux Ropes R. Kieokaew et al.
85. Interplanetary shock wave extent in the inner heliosphere as observed by multiple spacecraft A. de Lucas et al.
86. Evidence of a complex structure within the 2013 August 19 coronal mass ejection L. Rodríguez-García et al.
87. The impact of solar - terrestrial plasma and magnetic field on the detection of space-borne gravitational wave detections W. Su
88. Multiple, distant (40°) in situ observations of a magnetic cloud and a corotating interaction region complex C. Farrugia et al.
89. ON SUN-TO-EARTH PROPAGATION OF CORONAL MASS EJECTIONS: II. SLOW EVENTS AND COMPARISON WITH OTHERS Y. Liu et al.
90. Study of the Development of ICME Induced Geomagnetic Storms during Solar Cycle 24 B. Aljehani et al.
91. Magnetic helicity in the solar wind C. Smith
92. Consequences of the force‐free model of magnetic clouds for their heliospheric evolution M. Leitner et al.
93. On the propagation of a geoeffective coronal mass ejection during 15–17 March 2015 Y. Wang et al.
94. Study of flux-rope characteristics at sub-astronomical-unit distances using the Helios 1 and 2 spacecraft A. Raghav et al.
95. A Current Sheet Formation in a Turbulent ICME Sheath and Associated Particle Enhancement K. Ghag et al.
96. A model of the magnetosheath magnetic field during magnetic clouds L. Turc et al.
97. Field‐Aligned Current and Polar Cap Potential and Geomagnetic Disturbances: A Review of Cross‐Correlation Analysis B. Adhikari et al.
98. Coherence of Coronal Mass Ejections in Near-Earth Space M. Owens
99. Inversion studies of magnetic cloud structure at 0.7 AU: Solar cycle variation T. Mulligan et al.
100. Multispacecraft Study of the Interaction Between an Interplanetary Shock and a Solar Wind Flux Rope X. Blanco‐Cano et al.
101. Characteristics and evolution of sheath and leading edge structures of interplanetary coronal mass ejections in the inner heliosphere based on Helios and Parker Solar Probe observations M. Temmer & V. Bothmer
102. Coronal flux ropes and their interplanetary counterparts N. Gopalswamy et al.
103. Size and energy distributions of interplanetary magnetic flux ropes H. Feng et al.
104. CONNECTING SPEEDS, DIRECTIONS AND ARRIVAL TIMES OF 22 CORONAL MASS EJECTIONS FROM THE SUN TO 1 AU C. Möstl et al.
105. Magnetic Field Configuration Models and Reconstruction Methods for Interplanetary Coronal Mass Ejections N. Al-Haddad et al.
106. Relationship between X-class Flares and Geomagnetic Effects Y. ZHU et al.
107. Possible north–south asymmetry related to the mean B of interplanetary coronal mass ejections T. Baranyi & A. Ludmány
108. Magnetic Clouds at/near the 2007 – 2009 Solar Minimum: Frequency of Occurrence and Some Unusual Properties R. Lepping et al.
109. Radial Sizes and Expansion Behavior of ICMEs in Solar Cycles 23 and 24 W. Mishra  et al.
110. Model-independent large-scale magnetohydrodynamic quantities in magnetic clouds S. Dasso et al.
111. Magnetic Clouds: Solar Cycle Dependence, Sources, and Geomagnetic Impacts Y. Li et al.
112. Modeling and Measuring the Flux Reconnected and Ejected by the Two-Ribbon Flare/CME Event on 7 November 2004 D. Longcope et al.
113. CME–CME Interactions as Sources of CME Geoeffectiveness: The Formation of the Complex Ejecta and Intense Geomagnetic Storm in 2017 Early September C. Scolini et al.
114. On the Role of Alfvénic Fluctuations as Mediators of Coherence within Interplanetary Coronal Mass Ejections: Investigation of Multi-spacecraft Measurements at 1 au C. Scolini et al.
115. Soft X-ray Solar Activities Associated with Interplanetary Magnetic Flux Ropes S. Watari et al.
116. Properties of Interplanetary Coronal Mass Ejections N. Gopalswamy
117. LINKING REMOTE IMAGERY OF A CORONAL MASS EJECTION TO ITS IN SITU SIGNATURES AT 1 AU C. Möstl et al.
118. Propagation of coronal mass ejections from the Sun to the Earth W. MISHRA & L. TERIACA
119. BepiColombo Science Investigations During Cruise and Flybys at the Earth, Venus and Mercury V. Mangano et al.
120. Comparative ionospheric impacts and solar origins of nine strong geomagnetic storms in 2010–2015 B. Wood et al.
121. Determining the Intrinsic CME Flux Rope Type Using Remote-sensing Solar Disk Observations E. Palmerio et al.
122. A comparison between the geoeffectiveness of north‐south and south‐north magnetic clouds and an associated prediction C. Wu et al.
123. The Effects of Uncertainty in Initial CME Input Parameters on Deflection, Rotation, Bz, and Arrival Time Predictions C. Kay & N. Gopalswamy
124. THE FORMATION AND LAUNCH OF A CORONAL MASS EJECTION FLUX ROPE: A NARRATIVE BASED ON OBSERVATIONS T. Howard & C. DeForest
125. Geo-effectiveness of ICMES/MCs of different magnetic-polarity configurations W. Alotaibi et al.
126. Interplanetary small‐ and intermediate‐sized magnetic flux ropes during 1995–2005 H. Feng et al.
127. Identification of coherent structures in space plasmas: the magnetic helicity–PVI method F. Pecora et al.
128. EVOLUTION OF CORONAL MASS EJECTION MORPHOLOGY WITH INCREASING HELIOCENTRIC DISTANCE. II. IN SITU OBSERVATIONS N. Savani et al.
129. Characteristic Scales of Complexity and Coherence within Interplanetary Coronal Mass Ejections: Insights from Spacecraft Swarms in Global Heliospheric Simulations C. Scolini et al.
130. Magnetic cloud models with bent and oblate cross-section boundaries P. Démoulin & S. Dasso
131. Helicity of magnetic clouds and their associated active regions R. Leamon et al.
132. The Space Weather Context of the First Extreme Event of Solar Cycle 25, on 2022 September 5 E. Paouris et al.
133. Solar Wind Properties and Geospace Impact of Coronal Mass Ejection‐Driven Sheath Regions: Variation and Driver Dependence E. Kilpua et al.
134. Propagation of Fast Coronal Mass Ejections and Shock Waves Associated with Type II Radio-Burst Emission: An Analytic Study P. Corona-Romero et al.
135. In situ properties of small and large flux ropes in the solar wind M. Janvier et al.
136. Yearly Comparison of Magnetic Cloud Parameters, Sunspot Number, and Interplanetary Quantities for the First 18 Years of the Wind Mission R. Lepping et al.
137. Interplanetary Magnetic Flux Ropes as Agents Connecting Solar Eruptions and Geomagnetic Activities K. Marubashi et al.
138. First Simultaneous In Situ Measurements of a Coronal Mass Ejection by Parker Solar Probe and STEREO-A R. Winslow et al.
139. CHALLENGING SOME CONTEMPORARY VIEWS OF CORONAL MASS EJECTIONS. II. THE CASE FOR ABSENT FILAMENTS T. Howard et al.
140. Multipoint Observations of the June 2012 Interacting Interplanetary Flux Ropes E. Kilpua et al.
141. Geometrical Relationship Between Interplanetary Flux Ropes and Their Solar Sources K. Marubashi et al.
142. LEARNING FROM THE OUTER HELIOSPHERE: INTERPLANETARY CORONAL MASS EJECTION SHEATH FLOWS AND THE EJECTA ORIENTATION IN THE LOWER CORONA R. Evans et al.
143. How the CME on 2023 April 21 Triggered the First Severe Geomagnetic Storm of Solar Cycle 25 E. Paouris et al.
144. Properties of magnetic clouds and geomagnetic storms associated with eruption of coronal sigmoids R. Leamon et al.
145. Solar cycle–dependent helicity transport by magnetic clouds B. Lynch et al.
146. Polarization Diagnostics Applied to Coronal Mass Ejections and the Background Solar Wind S. Gibson et al.
147. Elliptical magnetic clouds and geomagnetic storms I. Antoniadou et al.
148. An Alternative Method for Identifying Interplanetary Magnetic Cloud Regions A. Ojeda-Gonzalez et al.
149. Using Global Simulations to Relate the Three‐Part Structure of Coronal Mass Ejections to In Situ Signatures P. Riley et al.
150. On Flare-CME Characteristics from Sun to Earth Combining Remote-Sensing Image Data with In Situ Measurements Supported by Modeling M. Temmer et al.
151. Disparities in Magnetic Cloud Observations between Two Spacecraft Having Small Radial and Angular Separations near 1 au A. Agarwal & W. Mishra
152. An Analytical Diffusion–Expansion Model for Forbush Decreases Caused by Flux Ropes M. Dumbović et al.
153. Radial evolution of the April 2020 stealth coronal mass ejection between 0.8 and 1 AU J. Freiherr von Forstner et al.
154. Study of the Orientation of Erupting Magnetic Flux Ropes in Coronal Mass Ejections from the Solar Corona to 1 au Y. Wang 王 et al.
155. Ulysses Observations at Solar Maximum: Introduction E. Smith & R. Marsden
156. Using CME Progenitors to Assess CME Geoeffectiveness K. Mundra et al.
157. Mass loss of “Hot Jupiters”—Implications for CoRoT discoveries. Part I: The importance of magnetospheric protection of a planet against ion loss caused by coronal mass ejections M. Khodachenko et al.
158. Three-Dimensional Reconstruction of Two Solar Coronal Mass Ejections Using the STEREO Spacecraft T. Howard & S. Tappin
159. An Ensemble Study of a January 2010 Coronal Mass Ejection (CME): Connecting a Non-obvious Solar Source with Its ICME/Magnetic Cloud D. Webb et al.
160. Exploring the biases of a new method based on minimum variance for interplanetary magnetic clouds P. Démoulin et al.
161. Deriving CME Density From Remote Sensing Data and Comparison to In‐Situ Measurements M. Temmer et al.
162. Influence of the Deformation of Coronal Mass Ejections on Their in-Situ Fitting with Circular-Cross-Section Flux Rope Models B. Zhuang et al.
163. Determination of magnetic cloud parameters and prediction of magnetic storm intensity N. Barkhatov & E. Kalinina
164. ARRIVAL TIME CALCULATION FOR INTERPLANETARY CORONAL MASS EJECTIONS WITH CIRCULAR FRONTS AND APPLICATION TOSTEREOOBSERVATIONS OF THE 2009 FEBRUARY 13 ERUPTION C. Möstl et al.
165. Unraveling the Internal Magnetic Field Structure of the Earth-directed Interplanetary Coronal Mass Ejections During 1995 – 2015 T. Nieves-Chinchilla et al.
166. From Pseudostreamer Jets to Coronal Mass Ejections: Observations of the Breakout Continuum P. Kumar et al.
167. Solar cycle evolution of the structure of magnetic clouds in the inner heliosphere T. Mulligan et al.
168. Implications of Non-cylindrical Flux Ropes for Magnetic Cloud Reconstruction Techniques and the Interpretation of Double Flux Rope Events M. Owens et al.
169. Magnetic Clouds Observed at 1 Au During the Period 2000–2003 T. Nieves-Chinchilla et al.
170. On the three-dimensional configuration of coronal mass ejections H. Cremades & V. Bothmer
171. Coronal Magnetic Structure of Earthbound CMEs and In Situ Comparison E. Palmerio et al.
172. Superexpansion of interplanetary coronal mass ejection observed by Solar Orbiter and Wind spacecraft within 0.14 au radial separation S. Soni et al.
173. Flux Rope Modeling of the 2022 September 5 Coronal Mass Ejection Observed by Parker Solar Probe and Solar Orbiter from 0.07 to 0.69 au E. Davies et al.
174. Using the Evolution of Coronal Dimming Regions to Probe the Global Magnetic Field Topology G. Attrill et al.
175. Magnetic clouds and origins in STEREO era L. Yan et al.
176. A Solar‐Centric Approach to Improving Estimates of Exposure Processes for Coronal Mass Ejections K. Kirchen et al.
177. The solar magnetic field S. Solanki et al.
178. Coronal Mass Ejections and Forbush Decreases H. Cane
179. Solar Weather Event Modelling and Prediction M. Messerotti et al.
180. Investigating the Asymmetry of Magnetic Field Profiles of “Simple” Magnetic Ejecta through an Expansion-modified Flux Rope Model W. Yu et al.
181. On the Analysis of the Complex Forbush Decreases of January 2005 A. Papaioannou et al.
182. Rotation and interaction of the CMEs of September 8 and 10, 2014, tested with EUHFORIA A. Maharana et al.
183. The evolution of coronal mass ejections in the inner heliosphere: Implementing the spheromak model with EUHFORIA C. Verbeke et al.
184. Anisotropy of magnetic field fluctuations in an average interplanetary magnetic cloud at 1 AU T. Narock & R. Lepping
185. Systems theory for geospace plasma dynamics D. Vassiliadis
186. Solar Stormwatch: tracking solar eruptions L. Barnard et al.
187. THE SOLAR ORIGIN OF SMALL INTERPLANETARY TRANSIENTS A. Rouillard et al.
188. Multi-spacecraft Observations of the Evolution of Interplanetary Coronal Mass Ejections between 0.3 and 2.2 au: Conjunctions with the Juno Spacecraft E. Davies et al.
189. Origin and Ion Charge State Evolution of Solar Wind Transients during 4 – 7 August 2011 D. Rodkin et al.
190. Deriving the Interaction Point between a Coronal Mass Ejection and High-speed Stream: A Case Study A. Remeshan et al.
191. Observations of medium-scale magnetic ropes in interplanetary space Q. Song & D. Wu
192. A solar storm observed from the Sun to Venus using the STEREO, Venus Express, and MESSENGER spacecraft A. Rouillard et al.
193. Progressive Transformation of a Flux Rope to an ICME S. Dasso et al.
194. Evolution of coronal mass ejections with and without sheaths from the inner to the outer heliosphere: Statistical investigation for 1975 to 2022 C. Larrodera & M. Temmer
195. Magnetic clouds: A statistical study of magnetic helicity A. Gulisano et al.
196. The draping of heliospheric magnetic fields upstream of coronal mass ejecta G. Jones et al.
197. Average Magnetic Field Magnitude Profiles of Wind Magnetic Clouds as a Function of Closest Approach to the Clouds’ Axes and Comparison to Model R. Lepping et al.
198. Ensemble Prediction of a Halo Coronal Mass Ejection Using Heliospheric Imagers T. Amerstorfer et al.
199. A Data-driven, Physics-based Transport Model of Solar Energetic Particles Accelerated by Coronal Mass Ejection Shocks Propagating through the Solar Coronal and Heliospheric Magnetic Fields M. Zhang et al.
200. ROTATION OF CORONAL MASS EJECTIONS DURING ERUPTION B. Lynch et al.
201. Multi-Spacecraft Observations of an Interplanetary Coronal Mass Ejection Interacting with Two Solar-Wind Regimes Observed by the Ulysses and Twin-STEREO Spacecraft M. Maunder et al.
202. Predictions of Energy and Helicity in Four Major Eruptive Solar Flares M. Kazachenko et al.
203. 22-year cycle in the frequency of aurora occurrence in XIX century: Latitudinal effects N. Ptitsyna et al.
204. The Structural Connection between Coronal Mass Ejection Flux Ropes near the Sun and at 1 au H. Xie et al.
205. Partially ejected flux ropes: Implications for interplanetary coronal mass ejections S. Gibson & Y. Fan
206. Earth-affecting solar transients: a review of progresses in solar cycle 24 J. Zhang et al.
207. CHALLENGING SOME CONTEMPORARY VIEWS OF CORONAL MASS EJECTIONS. I. THE CASE FOR BLAST WAVES T. Howard & V. Pizzo
208. Tracking magnetic flux and helicity from the Sun to Earth J. Thalmann et al.
209. Difference in the parameters of ICMEs in Ejecta and Sheath region and their impact on Dst index during 1997–2014 A. Goswami
210. Magnetic cloud evolution: A comparison of analytical and numerical solutions M. Vandas & D. Odstrčil
211. Evidence of Magnetic Flux Ropes in the Solar Wind From Sigmoidal and non-Sigmoidal Active Regions C. Cid et al.
212. Identification of prominence ejecta by the proton distribution function and magnetic fine structure in interplanetary coronal mass ejections in the inner heliosphere S. Yao et al.
213. Relationship between interplanetary (IP) parameters and geomagnetic indices during IP shock events of 2005 J. Rathod et al.
214. A Helicity-Based Method to Infer the CME Magnetic Field Magnitude in Sun and Geospace: Generalization and Extension to Sun-Like and M-Dwarf Stars and Implications for Exoplanet Habitability S. Patsourakos & M. Georgoulis
215. Combining STEREO heliospheric imagers and Solar Orbiter to investigate the evolution of the 2022 March 10 CME B. Zhuang et al.
216. Auf Tuchfühlung mit der Sonne V. Bothmer
217. Multipoint Interplanetary Coronal Mass Ejections Observed with Solar Orbiter, BepiColombo, Parker Solar Probe, Wind, and STEREO-A C. Möstl et al.
218. A new method of measuring Forbush decreases M. Dumbović et al.
219. Modeling CME encounters at Parker Solar Probe with OSPREI: Dependence on photospheric and coronal conditions V. Ledvina et al.
220. Generic Magnetic Field Intensity Profiles of Interplanetary Coronal Mass Ejections at Mercury, Venus, and Earth From Superposed Epoch Analyses M. Janvier et al.
221. Radial variation of solar wind electrons inside a magnetic cloud observed at 1 and 5 AU R. Skoug et al.
222. Solar magnetic fields and geomagnetic events A. Pevtsov & R. Canfield
223. Sequential Small Coronal Mass Ejections Observed In Situ and in White-Light Images by Parker Solar Probe B. Wood et al.
224. Multiwavelength observation of a large-scale flux rope eruption above a kinked small filament P. Kumar & K. Cho
225. A Solar Eruption with Relatively Strong Geoeffectiveness Originating from Active Region Peripheral Diffusive Polarities R. Wang et al.
226. Magnetic structure of overexpanding coronal mass ejections: Numerical models
227. The smallest source region of an interplanetary magnetic cloud: A mini-sigmoid C. Mandrini et al.
228. Propagation and evolution of a magnetic cloud from ACE to Ulysses D. Du et al.
229. Comparative statistical study of characteristics of plasma in planar and non-planar ICME sheaths during solar cycles 23 and 24 Z. Shaikh et al.
230. A new model-independent method to compute magnetic helicity in magnetic clouds S. Dasso et al.
231. Interplanetary Coronal Mass Ejections Observed by MESSENGER and Venus Express S. Good & R. Forsyth
232. A Statistical Study of the Plasma and Composition Distribution inside Magnetic Clouds: 1998–2011 J. Huang et al.
233. 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.
234. ICMEs in the Outer Heliosphere and at High Latitudes: An Introduction R. von Steiger & J. Richardson
235. History and development of coronal mass ejections as a key player in solar terrestrial relationship N. Gopalswamy
236. Heliospheric evolution of solar wind small‐scale magnetic flux ropes M. Cartwright & M. Moldwin
237. Properties of slow magnetic clouds B. Tsurutani et al.
238. Predicting the magnetic vectors within coronal mass ejections arriving at Earth: 2. Geomagnetic response N. Savani et al.
239. Radial Evolution of Coronal Mass Ejections Between MESSENGER, Venus Express, STEREO, and L1: Catalog and Analysis T. Salman et al.
240. Strong geomagnetic activity forecast by neural networks under dominant southern orientation of the interplanetary magnetic field F. Valach et al.
241. Density variations of galactic cosmic rays in magnetic clouds A. Belov et al.
242. Deformation of ICMEs/MCs along their path A. Lynnyk et al.
243. Partially-erupting prominences: a comparison between observations and model-predicted observables D. Tripathi et al.
244. Merging of coronal and heliospheric numerical two‐dimensional MHD models D. Odstrcil et al.
245. Magnetic twist: a source and property of space weather J. Warnecke et al.
246. Solar origins of a strong stealth CME detected by Solar Orbiter J. O’Kane et al.
247. Can Alfvénic Fluctuations Affect the Correlation and Complexity of Magnetic Field of Magnetic Ejecta? A Case Study Based on Multi-spacecraft Measurements at 1 au C. Scolini et al.
248. Using the Coronal Evolution to Successfully Forward Model CMEs' In Situ Magnetic Profiles C. Kay & N. Gopalswamy
249. Long-term variations in the asymmetry of the magnetic field of the sun and heliosphere A. Mordvinov
250. Inconsistencies Between Local and Global Measures of CME Radial Expansion as Revealed by Spacecraft Conjunctions N. Lugaz et al.
251. Dynamic evolution of interplanetary shock waves driven by CMEs P. Corona-Romero & J. Gonzalez-Esparza
252. An Intense Geomagnetic Storm Originated from Stealth Coronal Mass Ejection: Remote and In Situ Observations by Near Radially Aligned Spacecraft P. Vemareddy & K. Selva Bharathi
253. Morphological Reconstruction of a Small Transient Observed by Parker Solar Probe on 2018 November 5 B. Wood et al.
254. Minimum Variance Analysis of Interplanetary Coronal Mass Ejections Around Solar Cycle 23 Maximum (1998–2002) E. Echer et al.
255. A Coronal Mass Ejection Impacting Parker Solar Probe at 14 Solar Radii C. Braga et al.
256. Improving the Arrival Time Estimates of Coronal Mass Ejections by Using Magnetohydrodynamic Ensemble Modeling, Heliospheric Imager Data, and Machine Learning T. Singh et al.
257. Coronal mass ejections and their sheath regions in interplanetary space E. Kilpua et al.
258. Magnetic clouds at sector boundaries N. Crooker et al.
259. A Parametric Study of Erupting Flux Rope Rotation B. Kliem et al.
260. High-rigidity Forbush decreases: due to CMEs or shocks? K. Arunbabu et al.
261. Effects of Geometries and Substructures of ICMEs on Geomagnetic Storms J. Lee et al.
262. Predicting the Magnetic Field of Earth-impacting CMEs C. Kay et al.
263. A Survey of Coronal Mass Ejections Measured In Situ by Parker Solar Probe during 2018–2022 T. Salman et al.
264. An Analysis of Eruptive Events Observed with the Hvar Observatory’s Double Solar Telescope L. Karbonini et al.
265. Main Time Characteristics of Cosmic Ray Variations and Related Parameters in Magnetic Clouds M. Abunina et al.
266. THE INTERNAL STRUCTURE OF CORONAL MASS EJECTIONS: ARE ALL REGULAR MAGNETIC CLOUDS FLUX ROPES? C. Jacobs et al.
267. EVOLUTION OF CORONAL MASS EJECTION MORPHOLOGY WITH INCREASING HELIOCENTRIC DISTANCE. I. GEOMETRICAL ANALYSIS N. Savani et al.
268. Magnetohydrodynamic simulation of interplanetary propagation of multiple coronal mass ejections with internal magnetic flux rope (SUSANOO‐CME) D. Shiota & R. Kataoka
269. Solar-wind predictions for the Parker Solar Probe orbit M. Venzmer & V. Bothmer
270. Automatic Detection of Large-scale Flux Ropes and Their Geoeffectiveness with a Machine-learning Approach S. Pal et al.
271. Variability of magnetospheric storms driven by different solar wind perturbations K. Huttunen et al.
272. Sixty-five years of solar radioastronomy: flares, coronal mass ejections and Sun–Earth connection M. Pick & N. Vilmer
273. Coronal Mass Ejections as Expanding Force-Free Structures M. Lyutikov & K. Gourgouliatos
274. Predicting the Magnetic Fields of a Stealth CME Detected by Parker Solar Probe at 0.5 au E. Palmerio et al.
275. Understanding the Effects of Spacecraft Trajectories through Solar Coronal Mass Ejection Flux Ropes Using 3DCOREweb H. Rüdisser et al.
276. OBSERVATIONS OF A SMALL INTERPLANETARY MAGNETIC FLUX ROPE ASSOCIATED WITH A MAGNETIC RECONNECTION EXHAUST H. Feng & D. Wu
277. Study of local regularities in solar wind data and ground magnetograms V. Klausner et al.
278. The geo-effectiveness of interplanetary small-scale magnetic fluxropes X. Zhang et al.
279. Geoeffectiveness of magnetic clouds occurred during solar cycle 23 S. Kumar & A. Raizada
280. Causes and consequences of magnetic cloud expansion P. Démoulin & S. Dasso
281. Observational Tracking of the 2D Structure of Coronal Mass Ejections Between the Sun and 1 AU N. Savani et al.
282. Interplanetary coronal mass ejections from MESSENGER orbital observations at Mercury R. Winslow et al.
283. Laboratory model of magnetosphere created by strong plasma perturbation with frozen-in magnetic field I. Shaikhislamov et al.
284. Expansion of magnetic clouds in the outer heliosphere A. Gulisano et al.
285. Effects of solar polarity reversals on geoeffective plasma streams T. Baranyi & A. Ludmány
286. A Study on the Nested Rings CME Structure Observed by the WISPR Imager Onboard Parker Solar Probe S. Shaik et al.
287. Comparison of Interplanetary Disturbances at theNEARSpacecraft with Coronal Mass Ejections at the Sun D. Rust et al.
288. Science objectives of the magnetic field experiment onboard Aditya-L1 spacecraft V. Yadav et al.
289. A Major Geomagnetic Storm in 2024 October Linked to Sympathetic Coronal Mass Ejection–Prominence Eruptions R. Wang et al.
290. Evolution of Coronal Mass Ejections and the Corresponding Forbush Decreases: Modeling vs. Multi-Spacecraft Observations M. Dumbović et al.
291. Can solar wind viscous drag account for coronal mass ejection deceleration? P. Subramanian et al.
292. EMPIRICAL RECONSTRUCTION AND NUMERICAL MODELING OF THE FIRST GEOEFFECTIVE CORONAL MASS EJECTION OF SOLAR CYCLE 24 B. Wood et al.
293. Investigating the Magnetic Structure of Interplanetary Coronal Mass Ejections Using Simultaneous Multispacecraft In Situ Measurements F. Regnault et al.
294. Propagation of Coronal Mass Ejections Observed During the Rising Phase of Solar Cycle 24 M. Syed Ibrahim et al.
295. Constraining the magnetic flux of the CME spheromak model in EUHFORIA with the magnetic helicity budget: Case study of 10 March 2022 CME S. Koya et al.
296. Uncovering the process that transports magnetic helicity to coronal mass ejection flux ropes S. Pal
297. Key Signatures of Prominence Materials and Category of Cold Materials Identified by Random Forest Classifier Z. Cheng et al.
298. Current Sheets, Plasmoids and Flux Ropes in the Heliosphere O. Khabarova et al.
299. On the Magnetic Field Evolution of Interplanetary Coronal Mass Ejections from 0.07 to 5.4 au C. Möstl et al.
300. Magnetic Reconnection Inside a Flux Transfer Event‐Like Structure in Magnetopause Kelvin‐Helmholtz Waves R. Kieokaew et al.
301. Nonlinear fluctuation analysis for a set of 41 magnetic clouds measured by the Advanced Composition Explorer (ACE) spacecraft A. Ojeda González et al.
302. Sector boundary transformation by an open magnetic cloud N. Crooker et al.
303. Analysis of the Internal Structure of the Streamer Blowout Observed by the Parker Solar Probe During the First Solar Encounter T. Nieves-Chinchilla et al.
304. Plasma depletion and mirror waves ahead of interplanetary coronal mass ejections Y. Liu et al.
305. Magnetic Structure and Propagation of Two Interacting CMEs From the Sun to Saturn E. Palmerio et al.
306. Solar cycle control of the magnetic cloud polarity and the geoeffectiveness Y. Li & J. Luhmann
307. Characteristics of the interplanetary coronal mass ejections in the heliosphere between 0.3 and 5.4 AU C. Wang et al.
308. Statistical Study of ICMEs and Their Sheaths During Solar Cycle 23 (1996 – 2008) E. Mitsakou & X. Moussas
309. How Can a Negative Magnetic Helicity Active Region Generate a Positive Helicity Magnetic Cloud? R. Chandra et al.
310. Predicting the magnetic vectors within coronal mass ejections arriving at Earth: 1. Initial architecture N. Savani et al.
311. The Magnetic Morphology of Magnetic Clouds: Multi-spacecraft Investigation of Twisted and Writhed Coronal Mass Ejections N. Al-Haddad et al.
312. THE MAJOR GEOEFFECTIVE SOLAR ERUPTIONS OF 2012 MARCH 7: COMPREHENSIVE SUN-TO-EARTH ANALYSIS S. Patsourakos et al.
313. The evidence for the evolution of interplanetary small flux ropes: Boundary layers H. Feng et al.
314. The Solar and Interplanetary Causes of Space Storms in Solar Cycle 23 V. Bothmer
315. On the preferential occurrence of interplanetary shocks in July and November: Causes (solar wind annual dependence) and consequences (intense magnetic storms) E. Echer et al.
316. In situ multi-spacecraft and remote imaging observations of the first CME detected by Solar Orbiter and BepiColombo E. Davies et al.
317. Cosmic ray spectral variations and anisotropy near Earth during the March 24, 1991, Forbush decrease M. Hofer & E. Flückiger
318. Propagation of Interplanetary Coronal Mass Ejections: The Drag-Based Model B. Vršnak et al.
319. Longitudinally spaced observations of a magnetic-cloud-like structure embedded in a co-rotating interaction region M. Maunder et al.
320. Investigation of dynamics of self-similarly evolving magnetic clouds G. Dalakishvili et al.
321. Multispacecraft recovery of a magnetic cloud and its origin from magnetic reconnection on the Sun C. Möstl et al.
322. Identification of configuration and boundaries of interplanetary magnetic clouds H. Feng et al.
323. INNER HELIOSPHERIC EVOLUTION OF A “STEALTH” CME DERIVED FROM MULTI-VIEW IMAGING AND MULTIPOINT IN SITU OBSERVATIONS. I. PROPAGATION TO 1 AU T. Nieves-Chinchilla et al.
324. Magnetic Flux Emergence, Activity, Eruptions and Magnetic Clouds: Following Magnetic Field from the Sun to the Heliosphere L. van Driel-Gesztelyi & J. Culhane
325. Prediction of the In Situ Coronal Mass Ejection Rate for Solar Cycle 25: Implications for Parker Solar Probe In Situ Observations C. Möstl et al.
326. Forbush Effects Created by Coronal Mass Ejections with Magnetic Clouds M. Abunina et al.
327. Cyclic Reversal of Magnetic Cloud Poloidal Field Y. Li et al.
328. Multiwavelength Study on Solar and Interplanetary Origins of the Strongest Geomagnetic Storm of Solar Cycle 23 P. Kumar et al.
329. On Modeling ICME Cross-Sections as Static MHD Columns D. Bhattacharjee et al.
330. Study of transient modulation of galactic cosmic rays due to interplanetary manifestations of coronal mass ejections: 2010 - 2017 M. Fadaaq & B. Badruddin
331. Two spacecraft observations of transient shocks and ejecta in the interplanetary medium J. González‐Esparza & S. Bravo
332. Simulating the Arrival of Multiple Coronal Mass Ejections That Triggered the Gannon Superstorm on 2024 May 10 S. Thampi et al.
333. Comparing the Properties of ICME‐Induced Forbush Decreases at Earth and Mars J. Freiherr von Forstner et al.
334. Solar origins of intense geomagnetic storms in 2002 as seen by the CORONAS-F satellite O. Panasenco et al.
335. Geoeffectiveness of magnetic cloud, shock/sheath, interaction region, high-speed stream and their combined occurrence . Badruddin & Y. Singh
336. Development of a formalism for computing transits of Earth-directed CMEs, plasma sheaths, and shocks. Towards a forecasting tool P. Corona-Romero & J. Gonzalez-Esparza
337. Tracing magnetic helicity from the solar corona to the interplanetary space M. Luoni et al.
338. Precessing planetary magnetospheres in SiO stars? H. Wiesemeyer et al.
339. Space weather: the solar perspective M. Temmer
340. Optimized Grad – Shafranov Reconstruction of a Magnetic Cloud Using STEREO-Wind Observations C. Möstl et al.
341. Analysis of Voyager 1 and Voyager 2 in situ CME observations S. Hosteaux et al.
342. Solar Sources of Interplanetary Magnetic Clouds Leading to Helicity Prediction R. Ulrich et al.
343. Peculiarities of medium parameter dynamics and cosmic ray density in strong Forbush decreases associated with magnetic clouds A. Petukhova et al.
344. A Catalog of Interplanetary Coronal Mass Ejections Observed by Juno between 1 and 5.4 au E. Davies et al.
345. Magnetic cloud evolution in a two‐speed solar wind J. Schmidt & P. Cargill
346. The features of microwave solar radiation observed in the stage of formation and initial propagation of geoeffective coronal mass ejections O. Sheiner & V. Fridman
347. New Metric for Minimum Variance Analysis Validation in the Study of Interplanetary Magnetic Clouds R. Rosa Oliveira et al.
348. Modeling a Coronal Mass Ejection from an Extended Filament Channel. II. Interplanetary Propagation to 1 au E. Palmerio et al.
349. Evolution of the Radial Size and Expansion of Coronal Mass Ejections Investigated by Combining Remote and In Situ Observations B. Zhuang et al.
350. How are Forbush decreases related to interplanetary magnetic field enhancements? K. Arunbabu et al.
351. An Observational Overview of Solar Flares L. Fletcher et al.
352. Dependence of the Geomagnetic Activity on the Structure of Magnetic Clouds N. Barkhatov et al.
353. Thermodynamic structure of collision‐dominated expanding plasma: Heating of interplanetary coronal mass ejections Y. Liu et al.
354. Writhed Analytical Magnetic Flux Rope Model A. Weiss et al.
355. Radial velocity map of solar wind transients in the field of view of STEREO/HI1 on 3 and 4 April 2010 X. Li et al.
356. Main time characteristics of cosmic ray variations and related parameters in magnetic clouds M. Abunina et al.
357. A coronal mass ejection encountered by four spacecraft within 1 au from the Sun: ensemble modelling of propagation and magnetic structure E. Palmerio et al.
358. Evolution of Coronal and Interplanetary Shock Waves Inferred from a Radio Burst K. Alielden
359. Role of coronal mass ejections in the heliospheric Hale cycle M. Owens et al.
360. Properties and processes that influence CME geo-effectiveness B. Lavraud & A. Rouillard
361. Solar wind signatures associated with magnetic clouds X. Blanco‐Cano & S. Bravo
362. SUN-TO-EARTH CHARACTERISTICS OF TWO CORONAL MASS EJECTIONS INTERACTING NEAR 1 AU: FORMATION OF A COMPLEX EJECTA AND GENERATION OF A TWO-STEP GEOMAGNETIC STORM Y. Liu et al.
363. Multiple Flux Rope Events at the High‐Latitude Magnetopause on January 26, 2001: Current Density Calculation
364. Helios 1 and 2 observations of particle decreases, ejecta, and magnetic clouds H. Cane et al.
365. Manifestation of configurations of magnetic clouds of the solar wind in geomagnetic activity N. Barkhatov et al.
366. Multiwavelength observations of a flux rope formation by series of magnetic reconnection in the chromosphere P. Kumar et al.
367. November 2004 space weather events: Real‐time observations and forecasts L. Trichtchenko et al.
368. Magnetic clouds with east/west orientated axes observed by Ulysses during solar cycle 23 A. Rees & R. Forsyth
369. Statistical Study of Geo-Effectiveness of Planar Magnetic Structures Evolved within ICME’s K. Ghag et al.
370. Geo-Effectiveness of Halo CMEs Based on Magnetic Parameters of the Solar Active Region P. Vijayalakshmi et al.
371. Geoeffectiveness of interplanetary shocks, magnetic clouds, sector boundary crossings and their combined occurrence E. Echer & W. Gonzalez
372. Structure of magnetic fields in NOAA active regions 0486 and 0501 and in the associated interplanetary ejecta V. Yurchyshyn et al.
373. RECONSTRUCTING THE MORPHOLOGY OF AN EVOLVING CORONAL MASS EJECTION B. Wood et al.
374. Predicting the geoeffective properties of coronal mass ejections: current status, open issues and path forward A. Vourlidas et al.
375. Daubechies wavelet coefficients: a tool to study interplanetary magnetic field fluctuations A. Ojeda González et al.
376. MEASURING THE MAGNETIC FIELD OF CORONAL MASS EJECTIONS NEAR THE SUN USING PULSARS T. Howard et al.
377. Statistical Plasma Properties of the Planar and Nonplanar ICME Magnetic Clouds during Solar Cycles 23 and 24 Z. Shaikh & A. Raghav
378. Relative occurrence rate and geoeffectiveness of large-scale types of the solar wind Y. Yermolaev et al.
379. New method for determining central axial orientation of flux rope embedded within current sheet using multipoint measurements Z. Li et al.
380. A New Technique to Provide Realistic Input to CME Forecasting Models N. Gopalswamy et al.
381. AN ANALYSIS OF THE ORIGIN AND PROPAGATION OF THE MULTIPLE CORONAL MASS EJECTIONS OF 2010 AUGUST 1 R. Harrison et al.
382. A new class of complex ejecta resulting from the interaction of two CMEs and its expected geoeffectiveness N. Lugaz & C. Farrugia
383. Heliospheric Evolution of Magnetic Clouds B. Vršnak et al.
384. Are CME-Related Dimmings Always a Simple Signature of Interplanetary Magnetic Cloud Footpoints? C. Mandrini et al.
385. Impact of the Solar Activity on the Propagation of ICMEs: Simulations of Hydro, Magnetic and Median ICMEs at the Minimum and Maximum of Activity B. Perri et al.
386. Inferring of flux rope orientation with the minimum variance analysis technique C. Xiao et al.
387. Magnetohydrodynamic Turbulent Evolution of a Magnetic Cloud in the Outer Heliosphere D. Telloni et al.
388. Wind Magnetic Clouds for the Period 2013 – 2015: Model Fitting, Types, Associated Shock Waves, and Comparisons to Other Periods R. Lepping et al.
389. Contribution of the ageing effect to the observed asymmetry of interplanetary magnetic clouds P. Démoulin et al.
390. Multi-Spacecraft Study of the 21 January 2005 ICME C. Foullon et al.
391. Cross Helicity of the 2018 November Magnetic Cloud Observed by the Parker Solar Probe S. Good et al.
392. Estimating the Magnetic Structure of an Erupting CME Flux Rope From AR12158 Using Data-Driven Modeling E. Kilpua et al.
393. ICMEs in the Inner Heliosphere: Origin, Evolution and Propagation Effects R. Forsyth et al.
394. Earth-Affecting Coronal Mass Ejections Without Obvious Low Coronal Signatures N. Nitta & T. Mulligan
395. The Sun and Space Weather N. Gopalswamy
396. Classification of Enhanced Geoeffectiveness Resulting from High-speed Solar Wind Streams Compressing Slower Interplanetary Coronal Mass Ejections S. Heinemann et al.
397. On the utility of flux rope models for CME magnetic structure below 30R⊙ B. Lynch et al.
398. PREDICTION OF GEOMAGNETIC STORM STRENGTH FROM INNER HELIOSPHERIC IN SITU OBSERVATIONS M. Kubicka et al.
399. The Helicity Sign of Flux Transfer Event Flux Ropes and Its Relationship to the Guide Field and Hall Physics in Magnetic Reconnection at the Magnetopause S. Dahani et al.
400. Solar Wind Sources and Their Variations Over the Solar Cycle R. Schwenn
401. Counterstreaming electrons in small interplanetary magnetic flux ropes H. Feng et al.
402. Evolution of a Coronal Mass Ejection with an Eruptive Prominence from the Corona to Interplanetary Space B. Zhuang et al.
403. On the Spatial Coherence of Magnetic Ejecta: Measurements of Coronal Mass Ejections by Multiple Spacecraft Longitudinally Separated by 0.01 au N. Lugaz et al.
404. The Eruption of a Magnetic Flux Rope Observed by Solar Orbiter and Parker Solar Probe D. Long et al.
405. The relationship between small interplanetary magnetic flux rope and the substorm expansion phase H. Feng et al.
406. CME Evolution in the Structured Heliosphere and Effects at Earth and Mars During Solar Minimum E. Palmerio et al.
407. An In Situ Interplanetary “U-burst”: Observation and Results J. Martínez Oliveros et al.
408. On the Mesoscale Structure of Coronal Mass Ejections at Mercury’s Orbit: BepiColombo and Parker Solar Probe Observations E. Palmerio et al.
409. Study of the radial dependence of Forbush decreases at 0.28–1 au using data from the Helios 1 and 2 spacecraft A. Belov et al.
410. Magnetic cloud Bs events and their dependence on cloud parameters X. Zhao et al.
411. Evolution of a Long‐Duration Coronal Mass Ejection and Its Sheath Region Between Mercury and Earth on 9–14 July 2013 N. Lugaz et al.
412. Interplanetary Coronal Mass Ejections Observed by Ulysses Through Its Three Solar Orbits D. Du et al.
413. Evolution of Coronal Mass Ejection Properties in the Inner Heliosphere: Prediction for the Solar Orbiter and Parker Solar Probe N. Al-Haddad et al.
414. Comparison of the low-frequency characteristics of the model solar wind spiral magnetic cloud with observed disturbances N. Barkhatov et al.
415. Comparison of the Low-Frequency Characteristics of a Model Solar Wind Spiral Magnetic Cloud with Observed Disturbances N. Barkhatov et al.
416. In Situ Signatures of Interchange Reconnection between Magnetic Clouds and Open Magnetic Fields: A Mechanism for the Erosion of Polar Coronal Holes? B. Lavraud et al.
417. Reconnection remnants in the magnetic cloud of October 18–19, 1995: A shock, monochromatic wave, heat flux dropout, and energetic ion beam M. Collier et al.
418. SMESE: A SMall Explorer for Solar Eruptions J. Vial et al.
419. Eruption and propagation of twisted flux ropes from the base of the solar corona to 1 au F. Regnault et al.
420. Understanding Interplanetary Coronal Mass Ejection Signatures R. Wimmer-Schweingruber et al.
421. Geoeffective Properties of Solar Transients and Stream Interaction Regions E. Kilpua et al.
422. Concerning the helium‐to‐hydrogen number density ratio in very slow ejecta and winds near solar minimum B. Vasquez et al.
423. Why have geomagnetic storms been so weak during the recent solar minimum and the rising phase of cycle 24? E. Kilpua et al.
424. A magnetic polarity and chirality analysis of ISEE 3 interplanetary magnetic clouds
425. On Fields and Mass Constraints for the Uniform Propagation of Magnetic-Flux Ropes Undergoing Isotropic Expansion D. Berdichevsky
426. Regarding the detectability and measurement of coronal mass ejections T. Howard
427. Tracking an Eruptive Intermediate Prominence Originating from the Farside of the Sun Q. Zhang et al.
428. On the relationship between interplanetary coronal mass ejections and magnetic clouds E. Kilpua et al.
429. Progress in space weather predictions and applications H. Lundstedt
430. Multiple magnetic clouds in interplanetary space Y. Wang et al.
431. A Coronal Mass Ejection and Magnetic Ejecta Observed In Situ by STEREO-A and Wind at 55° Angular Separation N. Lugaz et al.
432. Alfvén Ion Cyclotron Waves in Sheath Regions Driven by Interplanetary Coronal Mass Ejections M. Ala‐Lahti et al.
433. The Magnetic Field Structure of Coronal Mass Ejections: A More Realistic Representation N. Al-Haddad & N. Lugaz
434. Wind Magnetic Clouds for 2010 – 2012: Model Parameter Fittings, Associated Shock Waves, and Comparisons to Earlier Periods R. Lepping et al.
435. SMALL-SCALE MAGNETIC ISLANDS IN THE SOLAR WIND AND THEIR ROLE IN PARTICLE ACCELERATION. I. DYNAMICS OF MAGNETIC ISLANDS NEAR THE HELIOSPHERIC CURRENT SHEET O. Khabarova et al.
436. Cross helicity of interplanetary coronal mass ejections at 1 au S. Good et al.
437. Resolving the Ambiguity of a Magnetic Cloud’s Orientation Caused by Minimum Variance Analysis Comparing it with a Force-Free Model R. Rosa Oliveira et al.
438. Internal Structure of the 2019 April 2 CME B. Wood et al.
439. CME propagation through the heliosphere: Status and future of observations and model development M. Temmer et al.
440. Deflection flows ahead of ICMEs as an indicator of curvature and geoeffectiveness Y. Liu et al.
441. Combined method for detecting hidden anomalies in galactic cosmic ray variations V. Borog et al.
442. Magnetic Helicity Generation by Solar Differential Rotation C. DeVore
443. Testing the Flux Rope Paradigm for Coronal Mass Ejections Using a Three-spacecraft Encounter Event B. Wood & P. Hess
444. ROTATION OF WHITE-LIGHT CORONAL MASS EJECTION STRUCTURES AS INFERRED FROM LASCO CORONAGRAPH V. Yurchyshyn et al.
445. Analysis of Coronal Mass Ejection Flux Rope Signatures Using 3DCORE and Approximate Bayesian Computation A. Weiss et al.
446. Characterizing the specific energy and pressure in near-Earth magnetic clouds D. Bhattacharjee et al.
447. Two‐step forecast of geomagnetic storm using coronal mass ejection and solar wind condition R. Kim et al.
448. The magnetic flux and self-inductivity of a thick toroidal current T. ŽIC et al.
449. A CORONAL HOLE'S EFFECTS ON CORONAL MASS EJECTION SHOCK MORPHOLOGY IN THE INNER HELIOSPHERE B. Wood et al.
450. Observations and analysis of small-scale magnetic flux ropes in the solar wind J. Zheng & Q. Hu
451. Magnetic Helicity Signs and Flaring Propensity: Comparing the Force-free Parameter with the Helicity Signs of Hα Filaments and X-Ray Sigmoids V. Aparna et al.
452. Non-conventional approach for deriving the radial sizes of coronal mass ejections at different instances: discrepancies in the estimates between remote and in situ observations A. Agarwal & W. Mishra
453. Unexpected major geomagnetic storm caused by faint eruption of a solar trans-equatorial flux rope W. Teng et al.
454. Stream Interactions and Interplanetary Coronal Mass Ejections at 0.72 AU L. Jian et al.
455. The Presence of Turbulent and Ordered Local Structure within the ICME Shock-sheath and Its Contribution to Forbush Decrease Z. Shaikh et al.
456. Modelling and observations of photospheric magnetic helicity P. Démoulin & E. Pariat
457. Fitting of expanding magnetic clouds: A statistical study A. Lynnyk & M. Vandas
458. Magnetic helicity analysis of an interplanetary twisted flux tube S. Dasso et al.
459. Stationary strong magnetohydrodynamic discontinuities and pressure balanced structures in the solar wind stream S. Grib
460. Evolution of the interacting coronal mass ejections that drove the great geomagnetic storm of 10 May 2024 S. Khuntia et al.
461. Multi-spacecraft observed magnetic clouds as seen by Helios mission A. de Lucas et al.
462. STEREO IMPACT Investigation Goals, Measurements, and Data Products Overview J. Luhmann et al.
463. Study of two interacting interplanetary coronal mass ejections encountered by Solar Orbiter during its first perihelion passage D. Telloni et al.
464. Magnetic Field Observations of Transient Events at Ulysses, 1996–2000 R. Forsyth et al.
465. Pursuing Forecasts of the Behavior and Arrival of Coronal Mass Ejections through Modeling and Observations H. Cremades
466. A new model for the topology of magnetic clouds in the solar wind M. Hidalgo et al.
467. Observations of ICMEs and ICME-like Solar Wind Structures from 2007 – 2010 Using Near-Earth and STEREO Observations E. Kilpua et al.
468. Assessment of the near-Sun magnetic field of the 10 March 2022 coronal mass ejection observed by Solar Orbiter S. Koya et al.
469. Development of a formalism for computing in situ transits of Earth-directed CMEs – Part 2: Towards a forecasting tool P. Corona-Romero & P. Riley
470. Interplanetary flux rope ejected from an X-ray bright point C. Mandrini et al.
471. A statistical study of the properties of interplanetary coronal mass ejections from 0.3 to 5.4AU Y. Liu et al.
472. Estimation of the bias of the Minimum Variance technique in the determination of magnetic clouds global quantities and orientation A. Gulisano et al.
473. On the variation of interplanetary magnetic cloud type through solar cycle 23: Wind events R. Lepping & C. Wu
474. Relationship between X-class Flares and Geomagnetic Effects Y. Zhu et al.
475. Magnetic helicity content in solar wind flux ropes S. Dasso
476. Galactic Cosmic Ray Density Variations in Magnetic Clouds A. Belov et al.
477. Inferences About the Magnetic Field Structure of a CME with Both In Situ and Faraday Rotation Constraints B. Wood et al.
478. Near-Sun In Situ and Remote-sensing Observations of a Coronal Mass Ejection and its Effect on the Heliospheric Current Sheet O. Romeo et al.
479. CME Disturbance Forecasting G. Siscoe & R. Schwenn
480. Small interplanetary magnetic flux rope H. Feng et al.
481. Complex Evolution of Coronal Mass Ejections in the Inner Heliosphere as Revealed by Numerical Simulations and STEREO Observations: A Review N. Lugaz et al.
482. The Alpha Effect and the Observed Twist and Current Helicity of Solar Magnetic Fields K. Kuzanyan et al.
483. The effects of expansion and turbulence on the interplanetary evolution of a magnetic cloud M. Sangalli et al.
484. Effects of coronal mass ejection orientation on its propagation in the heliosphere K. Martinić et al.
485. Forecasting the properties of the solar wind using simple pattern recognition P. Riley et al.
486. Tracking a Ulysses High-latitude ICME Event Back to Its Solar Origins C. Dumitrache et al.
487. Forecasting Periods of Strong Southward Magnetic Field Following Interplanetary Shocks T. Salman et al.
488. Using Statistical Multivariable Models to Understand the Relationship Between Interplanetary Coronal Mass Ejecta and Magnetic Flux Ropes P. Riley & I. Richardson
489. Source and Propagation of a Streamer Blowout Coronal Mass Ejection Observed by the Parker Solar Probe K. Korreck et al.
490. Investigating plasma motion of magnetic clouds at 1 AU through a velocity‐modified cylindrical force‐free flux rope model Y. Wang et al.
491. Determination of coronal mass ejection orientation and consequences for their propagation K. Martinić et al.
492. Magnetic cloud prediction model for forecasting space weather relevant properties of Earth-directed coronal mass ejections S. Pal et al.
493. Processes that Promote and Deplete the Exosphere of Mercury R. Killen et al.
494. Modeling the behavior of the cosmic ray density in magnetic clouds A. Belov et al.
495. Comparison of CME and ICME Structures Derived from Remote-Sensing and In Situ Observations V. Bothmer & N. Mrotzek
496. Connecting Coronal Mass Ejections and Magnetic Clouds: A Case Study Using an Event from 22 June 2009 B. Wood et al.
497. COMPARISON OF MAGNETIC PROPERTIES IN A MAGNETIC CLOUD AND ITS SOLAR SOURCE ON 2013 APRIL 11–14 P. Vemareddy et al.
498. Geomagnetic activity during the rising phase of solar cycle 24 I. Richardson
499. The Bastille day Magnetic Clouds and Upstream Shocks: Near-Earth Interplanetary Observations R. Lepping et al.
500. Advances in space research nonlinear dependence of Dst and AE indices on the electric field of magnetic clouds I. Plotnikov & E. Barkova
501. Forbush decrease spectrum in a magnetic cloud in the 2004 July 27 event A. Petukhova et al.
502. Magnetic Disconnections at the Boundary of a Small Interplanetary Magnetic Flux Rope Associated with a Reconnection Exhaust J. Wang et al.
503. Solar Filaments and Interplanetary Magnetic Field Bz V. Aparna & P. Martens
504. Solar and heliospheric geoeffective disturbances N. Crooker
505. MEASURING AN ERUPTIVE PROMINENCE AT LARGE DISTANCES FROM THE SUN. II. APPROACHING 1 AU T. Howard
506. Linking two consecutive nonmerging magnetic clouds with their solar sources S. Dasso et al.
507. Characteristics of Magnetic Helicity of Flux Transfer Events at the Magnetopause H. Bai et al.
508. OBSERVATIONS OF SEVERAL UNUSUAL PLASMA COMPOSITIONAL SIGNATURES WITHIN SMALL INTERPLANETARY MAGNETIC FLUX ROPES H. Feng & J. Wang
509. INFLUENCE OF THE AMBIENT SOLAR WIND FLOW ON THE PROPAGATION BEHAVIOR OF INTERPLANETARY CORONAL MASS EJECTIONS M. Temmer et al.
510. Peculiarities of medium parameter dynamics and cosmic ray density in strong Forbush decreases associated with magnetic clouds A. Petukhova et al.
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