49 citations as recorded by crossref.

1. Geomagnetically induced currents modelling and monitoring transformer neutral currents in Austria T. Halbedl et al.
2. The Evolution of Québec Earth Models Used to Model Geomagnetically Induced Currents D. Boteler
3. Geomagnetically Induced Currents Modeling and Forecasting A. Pulkkinen
4. Differential Magnetometer Measurements of Geomagnetically Induced Currents in a Complex High Voltage Network J. Hübert et al.
5. Modeling Geomagnetically Induced Currents From Magnetometer Measurements: Spatial Scale Assessed With Reference Measurements M. Butala et al.
6. Geomagnetically Induced Current Analysis in Malaysian Power Transmission System Z. Khurshid et al.
7. Implementing Geomagnetically Induced Currents Mitigation During the May 2024 “Gannon” G5 Storm: Research Informed Response by the New Zealand Power Network D. Mac Manus et al.
8. Modeling Geoelectric Fields and Geomagnetically Induced Currents Around New Zealand to Explore GIC in the South Island's Electrical Transmission Network T. Divett et al.
9. An Evaluation of the Frequency Independence Assumption of Power System Coefficients Used in Geomagnetically Induced Current Estimates R. Weigel & P. Cilliers
10. Differential magnetometer method applied to measurement of geomagnetically induced currents in Southern African power networks E. Matandirotya et al.
11. Validating GIC Models With Measurements in Austria: Evaluation of Accuracy and Sensitivity to Input Parameters R. Bailey et al.
12. Modeling geomagnetically induced currents D. Boteler & R. Pirjola
13. Geomagnetically induced currents: Science, engineering, and applications readiness A. Pulkkinen et al.
14. Multi‐Site Transfer Function Approach for Real‐Time Modeling of the Ground Electric Field Induced by Laterally‐Nonuniform Ionospheric Source M. Kruglyakov et al.
15. Berechnung von geomagnetisch induzierten Strömen auf Basis eines dreidimensionalen Leitfähigkeitsmodells M. Schühle & S. Tenbohlen
16. Geomagnetically induced currents in the Irish power network during geomagnetic storms S. Blake et al.
17. The South Atlantic Anomaly throughout the solar cycle J. Domingos et al.
18. The extreme solar and geomagnetic storms on 1940 March 20–25 H. Hayakawa et al.
19. Reduced Nodal Admittance Matrix Method for Probabilistic GIC Analysis in Power Grids M. Liu et al.
20. Versatile method for modeling geomagnetically induced currents in ground-based systems X. Wang & S. Zhang
21. A Detailed Model of the Irish High Voltage Power Network for Simulating GICs S. Blake et al.
22. A global climatological model of extreme geomagnetic field fluctuations N. Rogers et al.
23. Modified GIC Estimation Using 3‐D Earth Conductivity A. Kelbert & G. Lucas
24. New Detailed Modeling of GICs in the Spanish Power Transmission Grid J. Torta et al.
25. Analysis of geomagnetically induced currents at a low-latitude region over the solar cycles 23 and 24: comparison between measurements and calculations C. Barbosa et al.
26. Analysis of a geomagnetic induced current on a three-phase power transformer and power system A. Adiba Zawawi et al.
27. A Review of Geomagnetically Induced Current Effects on Electrical Power System: Principles and Theory Z. Abda et al.
28. Geomagnetically Induced Current Model in New Zealand Across Multiple Disturbances: Validation and Extension to Non‐Monitored Transformers D. Mac Manus et al.
29. A Risk Assessment Framework for the Socioeconomic Impacts of Electricity Transmission Infrastructure Failure Due to Space Weather: An Application to the United Kingdom E. Oughton et al.
30. Ensemble deep learning models for prediction and uncertainty quantification of ground magnetic perturbation T. Siddique & M. Mahmud
31. Geomagnetically Induced Current Modeling in New Zealand: Extreme Storm Analysis Using Multiple Disturbance Scenarios and Industry Provided Hazard Magnitudes D. Mac Manus et al.
32. Modelling geomagnetically induced currents in midlatitude Central Europe using a thin-sheet approach R. Bailey et al.
33. Geomagnetically induced currents in Uruguay: Sensitivity to modelling parameters R. Caraballo
34. Insight into impact of geomagnetically induced currents on power systems: Overview, challenges and mitigation V. Rajput et al.
35. Modeling the 10,000-Year Geomagnetic Disturbance Scenarios Based on Extreme Value Analysis M. Liu et al.
36. Robustness evaluation of power grids under extreme geomagnetic storm scenarios Q. Liu et al.
37. A similar coast effect of geoelectric field directions in a three-block boundary zone during geomagnetic storm pulses Z. Xin et al.
38. The Lehtinen–Pirjola method modified for efficient modelling of geomagnetically induced currents in multiple voltage levels of a power network R. Pirjola et al.
39. Modeling of Induction in Integrated Power-Gas Systems Due to Geomagnetic Disturbances M. Liu et al.
40. Geomagnetic Field Processes and Their Implications for Space Weather M. Mandea & A. Chambodut
41. Improved Model for GIC Calculation in the Mexican Power Grid R. Caraballo et al.
42. Earth’s geomagnetic environment—progress and gaps in understanding, prediction, and impacts H. Opgenoorth et al.
43. Frequency Considerations in GIC Applications L. Trichtchenko
44. A New Standalone Tool for DC‐Equivalent Network Generation and GIC Calculation in Power Grids With Multiple Voltage Levels S. Marsal et al.
45. Regional estimation of geomagnetically induced currents based on the local magnetic or electric field A. Viljanen et al.
46. Modeling Geomagnetically Induced Currents in Australian Power Networks Using Different Conductivity Models R. Marshall et al.
47. GIC-Inclusive State Estimator for Power System Awareness During Geomagnetic Disturbance Events G. Juvekar et al.
48. Transformer‐Level Modeling of Geomagnetically Induced Currents in New Zealand's South Island T. Divett et al.
49. Geomagnetically Induced Current Model Validation From New Zealand's South Island T. Divett et al.