Publications of Stefaan Poedts

A list of publications authored or co-authored by Stefaan Poedts, derived from the SAO/NASA Astrophysics Data System (ADS). The number in brackets after each title indicates the number of citations that the paper has received.

Orcid ID: 0000-0002-1743-0651

List of publications ordered by citations
Number of papers: 659 (refereed: 524)
No. of citations: 11352
First author papers: 53 (refereed: 29)

2026

1. Modelling the total solar eclipse in 2024 with COCONUT [1]
   Baratashvili, T., Wang, H. P., Sorokina, D., Lani, A. & Poedts, S., A&A, 705, A145
2. Advancing Heliophysics and Space Weather Modeling through Open Science [0]
   Corti, Claudio, Kuznetsova, Maria M., Reiss, Martin, Yue, Jia, Karpen, Judith T., Arge, Charles Nickolos, Bacchini, Fabio, Bard, Christopher, Bruinsma, Sean L., Caplan, Ronald M., Daldorff, Lars K. S., Deka, Pranab, DeVore, C. Richard, Elvidge, Sean, Ganushkina, Natalia Yu, Huba, Joseph, Jackson, Bernard V., Jordanova, Vania K., Linker, Jon, Liu, Han-Li, Luhmann, Janet G., Markidis, Stefano, Mayank, Prateek, Merkin, Viacheslav G., Moens, Nicolas, Odstrcil, Dusan, Omelchenko, Yuri A., Palmroth, Minna, Poedts, Stefaan, Ridley, Aaron J., Shou, Yinsi, Tenishev, Valeriy, Themens, David R., Tóth, Gábor, Wang, Wenbin, Wilhelm, Rostislav-Paul, Young, Matthew, Cecconi, Baptiste, Chou, Min-Yang, Zeeuw, Darren L. De, Delzanno, Gian Luca, Didigu, Chinwe, alaoui, mostafa el, Fung, Shing F., Green, Janet C., Huang, Zhenguang, Jian, Lan K., Landwer, Lois J., Lesko, Matthew, MacNeice, Peter, Masson, Arnaud, Mays, M. Leila, Mehta, Piyush M., Miesch, Mark Steven, Palmerio, Erika, Petrenko, Maksym, Provornikova, elena, Rastaetter, Lutz, Rusaitis, Liutauras, Sachdeva, Nishtha, Samara, Evangelia, Sur, Dibyendu, Taktakishvili, Aleksandre, Topper, Jack, Tsui, Tina, Verbeke, Christine, Wang, Jack Chieh, Wiegand, Chiu, Wiltberger, Michael, Zheng, Yihua, Bisi, Mario Mark, Georgoulis, Manolis, Kodikara, Timothy, Pulkkinen, Tuija I., Chartier, Alex T., Silva, Daniel E. da, Faturahman, Agri, Garcia-Sage, Katherine, Kondrashov, Dmitri, Ledvina, Vincent, Liu, Weihao, Pandey, Chetraj, Resnick, Elana M., Shi, Chen, Weigel, Robert S., Whitman, Kathryn, Zakharenkova, Irina & Zhang, Kun, 54528
3. Development of a High-order Flux Reconstruction Framework for Solar and Astrophysical Magnetohydrodynamics: Methods and Benchmarks [0]
   Dhib, Rayan, Ben Ameur, Firas, Parsani, Matteo, Lani, Andrea & Poedts, Stefaan, ApJS, 283, 75
4. BORAT-EM: High frequency electromagnetic solver for atmospheric entry blackout analysis [0]
   Giangaspero, Vincent F., Sharma, Vatsalya, Poedts, Stefaan & Lani, Andrea, Computer Physics Communications, 323, 110076
5. Data-driven magnetohydrodynamic simulation of the initiation of a coronal mass ejection with multiple stages [0]
   Guo, J. H., Poedts, S., Schmieder, B., Guo, Y., Zhou, C., Wu, H., Ni, Y. W., Zhong, Z., Zhou, Y. H., Li, S. H. & Chen, P. F., A&A, 707, L5
6. Elongation of a Solar Filament and its Three-dimensional Numerical Reconstruction for Magnetic Structures [0]
   Karki, Garima, Guo, Jinhan, Schmieder, Brigitte, Chandra, Ramesh, Démoulin, Pascal, Poedts, Stefaan & Gelly, Bernard, ApJ, 999, 148
7. Constraining the magnetic flux of the CME spheromak model in EUHFORIA with the magnetic helicity budget: Case study of 10 March 2022 CME [0]
   Koya, S., Sarkar, R., Maharana, A., Isavnin, A., Patsourakos, S., Poedts, S., Georgoulis, M. K., Nindos, A. & Murawski, K., A&A, 706, A139
8. Investigating the influence of the source-sink terms in a two-fluid global coronal model [0]
   Kumar, M., Kuźma, B., Poedts, S., Murawski, K. & Kilpua, E. K. J., A&A, 707, A21
9. Quasi-linear approach of bi-Kappa distributed electrons with dynamic κ parameter: EMEC instability [0]
   Moya, Pablo S., Navarro, Roberto E., Lazar, Marian, Yoon, Peter H., López, Rodrigo A. & Poedts, Stefaan, A&A, 707, A78
10. Quantifying the role of CME─CME interactions in geomagnetic storm severity: A case study using EUHFORIA [0]
    Sabri, Somaiyeh & Poedts, Stefaan, Advances in Space Research, 77, 4000
11. Evaluation of COSMIC-2 Satellite Data for foF2 and hmF2 Against Ground-Based Ionosondes and the PyIRI (2020) Model Across Middle to Low Latitudes [0]
    Seba, Ephrem Beshir, Jacobs, Carla, Melcot, Matthieu & Poedts, Stefaan, Space Weather, 24, e2024SW004321
12. Kinetic-Based Macro-Modeling of the Solar Wind at Large Heliocentric Distances: Kappa Electrons at the Exobase [0]
    Vinogradov, A., Lazar, M., Zouganelis, I., Pierrard, V. & Poedts, S., Journal of Geophysical Research (Space Physics), 131, e2025JA034770
13. COCONUT: A Coronal Model with an Energy Decomposition Strategy [1]
    Wang, Hao P., Poedts, S., Lani, A., Dhib, R., Linan, L., Baratashvili, T., Jeong, H.-J., Zhou, Yu H., Li, Yu C., Najafi-Ziyazi, M., Wang, J., Schmieder, B., Wang, W. S. & Husidic, E., ApJS, 283, 40
14. On energy consistency of intermediate states in HLL-type MHD Riemann solvers [0]
    Zhang, Fan, Lani, Andrea & Poedts, Stefaan, Journal of Computational Physics, 553, 114724

2025

1. Icarus 3.0: Dynamic heliosphere modelling [8]
   Baratashvili, T., Popescu Braileanu, B., Bacchini, F., Keppens, R. & Poedts, S., A&A, 694, A306
2. Investigating the impact of the dynamic solar wind on the propagation of a coronal mass ejection with two models and multi-spacecraft measurements [1]
   Baratashvili, T., Davies, E., Weiler, E., Schmieder, B., Démoulin, P. & Poedts, S., A&A, 704, A231
3. Integrating plasmasphere, ionosphere and thermosphere observations and models into a standardised open access research environment: The PITHIA-NRF international project [3]
   Belehaki, Anna, Häggström, Ingemar, Kiss, Tamas, Galkin, Ivan, Tjulin, Anders, Miháliková, Mária, Enell, Carl-Fredrik, Pierantoni, Gabriel, Chen, Yin, Sipos, Gergely, Bruinsma, Sean, Pierrard, Viviane, Altadill, David, Segarra, Antoni, Navas-Portella, Víctor, Pica, Emanuele, Spogli, Luca, Alfonsi, Lucilla, Cesaroni, Claudio, Romano, Vicenzo, Mainella, Sara, Vermicelli, Pietro, Verhulst, Tobias, Poedts, Stefaan, Hernández-Pajares, Manuel, Buresova, Dalia, Rusz, Jan, Chum, Jaroslav, Darrouzet, Fabien, Botek, Edith, Rothkaehl, Hanna, Matyjasiak, Barbara, Pożoga, Mariusz, Grzesiak, Marcin, Chan You Fee, David, Kagialis, Dimitris, Tsagouri, Ioanna, Thanasou, Angeliki, Herekakis, Themistocles, Chevalier, Jean-Marie, Bergeot, Nicolas, Winant, Alexandre, Mevius, Maaijke, Witvliet, Ben, Graffigna, Victoria, Marchaudon, Aurélie, Wenzel, David, Kriegel, Martin, Matzka, Jürgen, Kervalishvili, Guram, Raita, Tero, Hynönen, Reko & Watermann, Jurgen, Advances in Space Research, 75, 3082
4. Constraining the inner boundaries of COCONUT through plasma β and Alfvén speed [2]
   Brchnelova, M., Gudiksen, B., Carlsson, M., Lani, A. & Poedts, S., A&A, 693, A74
5. Density-gradient-driven drift-wave turbulence in the solar corona [0]
   Brchnelova, M., Pueschel, M. J. & Poedts, S., A&A, 698, A288
6. The Power of a Name: Toward a Unified Approach to Naming Space Weather Events [1]
   Chabanski, Sophie, Montety, Felix, Lilensten, Jean, Poedts, Stefaan & Spogli, Luca, Perspectives of Earth and Space Scientists, 6, e2025CN000285
7. Graph-GIC: A smart and parallelized geomagnetically induced current modelling algorithm based on graph theory for space weather applications [0]
   Chen, Wen, Yuan, Ding, Feng, Xueshang, Poedts, Stefaan, Zou, Zhengyang, Feng, Song, Zhu, Yuxuan & Yin, Tong, Advances in Space Research, 75, 2449
8. Toward High-order Solar Corona Simulations: A High-order Hyperbolized Poisson Approach for Magnetic Field Initialization [1]
   Dhib, Rayan, Ben Ameur, Firas, Sharma, Vatsalya, Lani, Andrea & Poedts, Stefaan, ApJ, 980, 163
9. Optimization of the FRi3D CME Model in EUHFORIA [0]
   Flossie, M., Maharana, A., Linan, L., Plets, K., Isavnin, A. & Poedts, S., Space Weather, 23, e2025SW004401
10. The Birth of a Major Coronal Mass Ejection with Intricate Magnetic Structure from Multiple Active Regions [6]
    Guo, J. H., Ni, Y. W., Schmieder, B., Guo, Y., Xia, C., Devi, P., Chandra, R., Poedts, S., Joshi, R., Zhou, Y. H., Li, H. T. & Chen, P. F., ApJ, 983, 48
11. Boltzmann─Poisson Theory of Nonthermal Self-gravitating Gases, Cold Dark Matter, and Solar Atmosphere [2]
    Hau, L.-N., Chang, C.-K., Lazar, M. & Poedts, S., ApJ, 981, 18
12. Modelling gyrosynchrotron emission from coronal energetic electrons in a CME flux rope [2]
    Husidic, E., Wijsen, N., Jebaraj, I. C., Vourlidas, A., Linan, L., Vainio, R. & Poedts, S., A&A, 701, A53
13. Prediction of Time-evolving Radial Magnetic Fields on the Solar Surface Using Deep Learning [4]
    Jeong, Hyun-Jin, Poedts, Stefaan, Wang, Haopeng, Dineva, Ekatarina, Gonidakis, Panagiotis, Carella, Francesco, Miloshevich, George, Linan, Luis & Lee, Harim, ApJ, 989, L31
14. Artificial-intelligence-based Reconstruction of Solar Farside Vector Magnetograms from Multispacecraft Extreme-ultraviolet Data [1]
    Jeong, Hyun-Jin, Park, Eunsu, Lee, Harim, Youn, Junmu, Jeon, Mingyu, Moon, Yong-Jae, Poedts, Stefaan, Carella, Francesco, Wang, Haopeng, Kim, Daeil, Kim, Youngjae & Kang, Jihye, ApJS, 281, 63
15. Extended Scenarios for Solar Radio Emissions With Downshifted Electron Beam Plasma Excitations [2]
    Lazar, M., López, R. A., Shaaban, S. M., Poedts, S. & Fichtner, H., Journal of Geophysical Research (Space Physics), 130, e2024JA033597
16. Dynamic spectra of solar radio emissions from weak-turbulence simulation [2]
    Lazar, M., Ziebell, L. F., Yoon, P. H., López, R. A. & Poedts, S., A&A, 696, A187
17. Fast Reconstruction of Solar Wind Magnetohydrodynamic Parameters at 0.1 au with Machine Learning [1]
    Li, Yucong, Wang, Haopeng, Jeong, Hyun-Jin, Shen, Fang, Poedts, Stefaan, Yang, Yi, Guo, Jinhan & Lin, Rongpei, ApJS, 281, 23
18. Data-constrained 3D magnetohydrodynamics simulation of a spiral jet caused by an unstable flux rope embedded in a fan─spine configuration [4]
    Li, Z. F., Guo, J. H., Cheng, X., Ding, M. D., Chitta, L. P., Peter, H., Poedts, S. & Calchetti, D., A&A, 696, L2
19. Coronal mass ejection propagation in the dynamically coupled space weather tool: COCONUT + EUHFORIA [10]
    Linan, L., Baratashvili, T., Lani, A., Schmieder, B., Brchnelova, M., Guo, J. H. & Poedts, S., A&A, 693, A229
20. Wave-Wave interactions in quantized Fermi gas [0]
    Maroosh, A., Rozina, Ch, Poedts, S. & Shah, H. A., Physica Scripta, 100, 045608
21. Magnetogram filtering techniques for global coronal modelling [2]
    Murteira, J., Brchnelova, M., Lani, A. & Poedts, S., RAS Techniques and Instruments, 4, rzaf030
22. Establishing a European Heliophysics Community (EHC) [0]
    Nakamura, Rumi, Dudok de Wit, Thierry, Jones, Geraint H., Taylor, Matt G. G. T., André, Nicolas, Goetz, Charlotte, Hadid, Lina Z., Hayes, Laura A., Hietala, Heli, Jackman, Caitríona M., Kepko, Larry, Marchaudon, Aurélie, Masters, Adam, Owens, Mathew, Partamies, Noora, Poedts, Stefaan, Rae, Jonathan, Shprits, Yuri, Temmer, Manuela, Verscharen, Daniel & Wimmer-Schweingruber, Robert F., Annales Geophysicae, 43, 855
23. Nonlinear wave-wave interaction of quantized upper hybrid waves with low frequency modes [0]
    Nourina, N., Rozina, Ch, Iqbal, Z., Poedts, S. & Abbas, G., Physica Scripta, 100, 015615
24. Interaction of longitudinal and transverse wave modes with quantum plasma [1]
    Rozina, Ch, Asma, A. & Poedts, S., Physica Scripta, 100, 045603
25. Influence of quantized magnetic field on electromagnetic wave propagation in counter-streaming plasmas [0]
    Rozina, Ch, Maryam, P., Poedts, S. & Iqbal, Z., Physica Scripta, 100, 105610
26. Investigation of the May 2024 Solar Storm Through EUHFORIA/Gorgon-Space Simulations and Global SuperDARN Observations [1]
    Sabri, Somaiyeh, Mahmoudian, Alireza & Poedts, Stefaan, Journal of Geophysical Research (Space Physics), 130, e2024JA033554
27. Flare Energetics, CME Launch and Heliospheric Propagation for the May 2024 Events, as Derived from Ensemble MHD Modelling [1]
    Schmieder, Brigitte, Guo, Jinhan, Aulanier, Guillaume, Maharana, Anwesha & Poedts, Stefaan, Solar Physics, 300, 132
28. Assessment of IRI2020 model accuracy in predicting ionospheric parameters: Insights from multiple ionosonde stations [2]
    Seba, Ephrem B. & Poedts, Stefaan, Advances in Space Research, 75, 918
29. Core-Halo Correlations of Solar Wind Electrons and Temperature Anisotropy Instabilities [1]
    Shaaban, S. M., Kennis, S., Lazar, M., Pierrard, V. & Poedts, S., Journal of Geophysical Research (Space Physics), 130, e2025JA033838
30. Cumulative Proton Right-handed Instabilities in the Young Solar Wind Observed by PSP [1]
    Shaaban, Shaaban M., Lazar, M., Fichtner, H., López, R. A. & Poedts, S., ApJ, 993, 1
31. FoMo white-light tool: Coupling with state-of-the-art numerical models [2]
    Sorokina, D., Van Doorsselaere, T., Lloveras, D. G., Linan, L. & Poedts, S., A&A, 701, A166
32. Time-evolving coronal modelling of the solar maximum around the solar storms in May 2024 by COCONUT [5]
    Wang, H. P., Poedts, S., Lani, A., Linan, L., Baratashvili, T., Zhang, F., Sorokina, D., Jeong, H.-J., Li, Y. C., Najafi-Ziyazi, M. & Schmieder, B., A&A, 702, A37
33. Efficient magnetohydrodynamic modelling of the time-evolving corona by COCONUT [8]
    Wang, H. P., Poedts, S., Lani, A., Brchnelova, M., Baratashvili, T., Linan, L., Zhang, F., Hou, D. W. & Zhou, Y. H., A&A, 694, A234
34. SIP-IFVM: Efficient time-accurate magnetohydrodynamic model of the corona and coronal mass ejections [6]
    Wang, H. P., Guo, J. H., Yang, L. P., Poedts, S., Zhang, F., Lani, A., Baratashvili, T., Linan, L., Lin, R. & Guo, Y., A&A, 693, A257
35. SIP-IFVM: An Observation-based Magnetohydrodynamic Model of a Coronal Mass Ejection [3]
    Wang, Hao P., Guo, Jin H., Poedts, S., Lani, A., Linan, L., Baratashvili, T., Yang, Li P., Jeong, H.-J., Wei, Wen W., Li, Cai X., Yang, Y., Li, Yu C., Wu, Hao, Guo, Yang & Schmieder, B., ApJS, 281, 43
36. SIP-IFVM: A Time-evolving Coronal Model with an Extended Magnetic Field Decomposition Strategy [9]
    Wang, Haopeng, Yang, Liping, Poedts, Stefaan, Lani, Andrea, Zhou, Yuhao, Gao, Yuhang, Linan, Luis, Lv, Jiakun, Baratashvili, Tinatin, Guo, Jinhan, Lin, Rong, Su, Zhan, Li, Caixia, Zhang, Man, Wei, Wenwen, Yang, Yun, Li, Yucong, Ma, Xinyi, Husidic, Edin, Jeong, Hyun-Jin, Najafi-Ziyazi, Mahdi, Wang, Juan & Schmieder, Brigitte, ApJS, 278, 59
37. Space-Weather Effects on Critical Infrastructure on Earth [0]
    Wedemeyer, Sven, Gullikstad Johnsen, Magnar, Antolin, Patrick, Rae, Jonathan & Poedts, Stefaan, Europhysics News, 56, 22

2024

1. On the asymptotic persistence of Langmuir modes in kinematically complex plasma flows [0]
   Arabuli, Ketevan, Rogava, Andria & Poedts, Stefaan, Astrophysics and Space Science, 369, 88
2. The operationally ready full 3D magnetohydrodynamic model from the Sun to Earth: COCONUT+Icarus [14]
   Baratashvili, T., Brchnelova, M., Linan, L., Lani, A. & Poedts, S., A&A, 690, A184
3. The effect of adaptive mesh refinement and grid stretching on the magnetized coronal mass ejection model in Icarus [6]
   Baratashvili, T. & Poedts, S., A&A, 683, A81
4. Multi-spacecraft study with the Icarus model: Modelling the propagation of CMEs to Mercury and Earth [3]
   Baratashvili, T., Grison, B., Schmieder, B., Démoulin, P. & Poedts, S., A&A, 689, A98
5. Density-gradient-driven drift waves in the solar corona [4]
   Brchnelova, M., Pueschel, M. J. & Poedts, S., Physics of Plasmas, 31, 092902
6. Input/Output Library for Higher-Order Computational Fluid Dynamics Data [2]
   Dhib, Rayan, Sharma, Vatsalya, Lani, Andrea & Poedts, Stefaan, SoftwareX, 28, 101943
7. Development of an implicit high-order Flux Reconstruction solver for high-speed flows on simplex elements [4]
   Dhib, Rayan, Ameur, Firas Ben, Vandenhoeck, Ray, Lani, Andrea & Poedts, Stefaan, Computer Physics Communications, 295, 109006
8. Modeling Ion Acceleration and Transport in Corotating Interaction Regions: The Mass-to-charge Ratio Dependence of the Particle Spectrum [3]
   Ding, Zheyi, Li, Gang, Wijsen, Nicolas, Poedts, Stefaan & Yao, Shuo, ApJ, 964, L8
9. Modelling two energetic storm particle events observed by Solar Orbiter using the combined EUHFORIA and iPATH models [14]
   Ding, Zheyi, Li, Gang, Mason, Glenn, Poedts, Stefaan, Kouloumvakos, Athanasios, Ho, George, Wijsen, Nicolas, Wimmer-Schweingruber, Robert F. & Rodríguez-Pacheco, Javier, A&A, 681, A92
10. Wide-band fluctuations of solar active regions probed with SHARP magnetograms [0]
    Dumbadze, G., Shergelashvili, B. M., Khodachenko, M. L. & Poedts, S., A&A, 683, A86
11. Quantifying the Expanding and Cooling Effects into the Double Adiabatic Evolution of the Solar Wind Through the Expanding Box Model [5]
    Echeverría-Veas, Sebastián, Moya, Pablo S., Lazar, Marian, Poedts, Stefaan & Asenjo, Felipe A., ApJ, 975, 112
12. On Boundary Conditions for Magnetohydrodynamic Waves in Flux Tubes with a Pressure Jump [2]
    Goedbloed, Hans & Poedts, Stefaan, Research Notes of the American Astronomical Society, 8, 60
13. Dependence of coronal mass ejections on the morphology and toroidal flux of their source magnetic flux ropes [5]
    Guo, J. H., Linan, L., Poedts, S., Guo, Y., Schmieder, B., Lani, A., Ni, Y. W., Brchnelova, M., Perri, B., Baratashvili, T., Li, S. T. & Chen, P. F., A&A, 690, A189
14. Modeling the propagation of coronal mass ejections with COCONUT: Implementation of the regularized Biot-Savart law flux rope model [14]
    Guo, J. H., Linan, L., Poedts, S., Guo, Y., Lani, A., Schmieder, B., Brchnelova, M., Perri, B., Baratashvili, T., Ni, Y. W. & Chen, P. F., A&A, 683, A54
15. Data-driven Modeling of a Coronal Magnetic Flux Rope: From Birth to Death [28]
    Guo, J. H., Ni, Y. W., Guo, Y., Xia, C., Schmieder, B., Poedts, S., Zhong, Z., Zhou, Y. H., Yu, F. & Chen, P. F., ApJ, 961, 140
16. Cross-field Diffusion Effects on Particle Transport in a Solar Coronal Flux Rope [6]
    Husidic, Edin, Wijsen, Nicolas, Linan, Luis, Brchnelova, Michaela, Vainio, Rami & Poedts, Stefaan, ApJ, 976, L31
17. Energetic particle acceleration and transport with the novel Icarus + PARADISE model [6]
    Husidic, Edin, Wijsen, Nicolas, Baratashvili, Tinatin, Poedts, Stefaan & Vainio, Rami, Journal of Space Weather and Space Climate, 14, 11
18. Magnetic connectivity from the Sun to the Earth with MHD models: I. Impact of the magnetic modelling on connectivity validation [4]
    Kennis, S., Perri, B. & Poedts, S., A&A, 691, A257
19. Numerical Experiment on the Influence of Granulation-induced Waves on Solar Chromosphere Heating and Plasma Outflows in a Magnetic Arcade [0]
    Kumar, M., Murawski, K., Kuźma, B., Kilpua, E. K. J., Poedts, S. & Erdélyi, R., ApJ, 975, 3
20. Magnetoacoustic cutoff effect in numerical simulations of the partially ionized solar atmosphere [7]
    Kuźma, Blazej, Kadowaki, Luis H. S., Murawski, Kris, Musielak, Zdzislaw E., Poedts, Stefaan, Yuan, Ding & Feng, Xueshang, Philosophical Transactions of the Royal Society of London Series A, 382, 20230218
21. Toroidal Miller-Turner and Soloviev coronal mass ejection models in EUHFORIA. I. Implementation [9]
    Linan, L., Maharana, A., Poedts, S., Schmieder, B. & Keppens, R., A&A, 681, A103
22. Toroidal modified Miller-Turner CME model in EUHFORIA: Validation and comparison with flux rope and spheromak [4]
    Maharana, A., Linan, L., Poedts, S. & Magdalenić, J., A&A, 691, A146
23. Corrigendum to "Implementation and validation of the FRi3D flux rope model in EUHFORIA" [Adv. Space Res. 70(6) (2022) 1641─1662] [3]
    Maharana, Anwesha, Isavnin, Alexey, Scolini, Camilla, Wijsen, Nicolas, Rodriguez, Luciano, Mierla, Marilena, Magdalenic, Jasmina & Poedts, Stefaan, Advances in Space Research, 73, 6310
24. Employing the Coupled EUHFORIA-OpenGGCM Model to Predict CME Geoeffectiveness [4]
    Maharana, Anwesha, Cramer, W. Douglas, Samara, Evangelia, Scolini, Camilla, Raeder, Joachim & Poedts, Stefaan, Space Weather, 22, e2023SW003715
25. Driven two-fluid slow magnetoacoustic waves in the solar chromosphere with a realistic ionisation profile [3]
    Niedziela, R., Murawski, K. & Poedts, S., A&A, 691, A254
26. Cannibals in PARADISE: The Effect of Merging Interplanetary Shocks on Solar Energetic Particle Events [7]
    Niemela, Antonio, Wijsen, Nicolas, Aran, Angels, Rodriguez, Luciano, Magdalenic, Jasmina & Poedts, Stefaan, ApJ, 967, L35
27. Influence of electrons on granulation-generated solar chromosphere heating and plasma outflows [0]
    Pelekhata, M., Murawski, K. & Poedts, S., A&A, 689, A155
28. EUHFORIA modelling of the Sun-Earth chain of the magnetic cloud of 28 June 2013 [5]
    Prete, G., Niemela, A., Schmieder, B., Al-Haddad, N., Zhuang, B., Lepreti, F., Carbone, V. & Poedts, S., A&A, 683, A28
29. Validation of EUHFORIA cone and spheromak coronal mass ejection models [6]
    Rodriguez, L., Shukhobodskaia, D., Niemela, A., Maharana, A., Samara, E., Verbeke, C., Magdalenic, J., Vansintjan, R., Mierla, M., Scolini, C., Sarkar, R., Kilpua, E., Asvestari, E., Herbst, K., Lapenta, G., Chaduteau, A. D., Pomoell, J. & Poedts, S., A&A, 689, A187
30. Calibrating the WSA Model in EUHFORIA Based on Parker Solar Probe Observations [11]
    Samara, E., Arge, C. N., Pinto, R. F., Magdalenić, J., Wijsen, N., Stevens, M. L., Rodriguez, L. & Poedts, S., ApJ, 971, 83
31. Studying the Spheromak Rotation in Data-constrained Coronal Mass Ejection Modeling with EUHFORIA and Assessing Its Effect on the B _z Prediction [15]
    Sarkar, Ranadeep, Pomoell, Jens, Kilpua, Emilia, Asvestari, Eleanna, Wijsen, Nicolas, Maharana, Anwesha & Poedts, Stefaan, ApJS, 270, 18
32. Numerical simulations of temperature anisotropy instabilities stimulated by suprathermal protons [2]
    Shaaban, S. M., López, R. A., Lazar, M. & Poedts, S., A&A, 691, A86
33. Decoding the formation of hammerhead ion populations observed by Parker Solar Probe [5]
    Shaaban, Shaaban M., Lazar, M., López, R. A., Yoon, P. H. & Poedts, S., A&A, 692, L6
34. Influence of magnetohydrodynamics configuration on aerothermodynamics during Martian reentry [8]
    Sharma, Vatsalya, Giangaspero, Vincent F., Poedts, Stefaan & Lani, Andrea, Physics of Fluids, 36, 036103
35. Polarization properties of the decameter spikes [2]
    Shevchuk, Mykola, Melnik, Valentin, Brazhenko, Anatolii, Dorovskyy, Vladimir, Frantsuzenko, Anatolii, Poedts, Stefaan & Magdalenic, Jasmina, Frontiers in Astronomy and Space Sciences, 11, 1396326
36. Magnetoacoustic wave propagation in the solar corona and filament dynamics [0]
    Somaiyeh, Sabri & Stefaan, Poedts, Scientific Reports, 14, 30723
37. CMEs evolve in the interplanetary medium to double their predicted geo-effectiveness [4]
    Soni, Shirsh Lata, Maharana, Anwesha, Guerrero, Antonio, Mishra, Wageesh, Poedts, Stefaan, Thampi, Smitha & Akhavan-Tafti, Mojtaba, A&A, 686, A23
38. MHD modelling of coronal streamers and their oscillations [4]
    Sorokina, D., Van Doorsselaere, T., Talpeanu, D.-C. & Poedts, S., A&A, 682, A168
39. The automatic identification and tracking of coronal flux ropes. II. New mathematical morphology-based flux rope extraction method and deflection analysis [5]
    Wagner, A., Bourgeois, S., Kilpua, E. K. J., Sarkar, R., Price, D. J., Kumari, A., Pomoell, J., Poedts, S., Barata, T., Erdélyi, R., Oliveira, O. & Gafeira, R., A&A, 683, A39
40. The effect of data-driving and relaxation models on magnetic flux rope evolution and stability [3]
    Wagner, A., Price, D. J., Bourgeois, S., Daei, F., Pomoell, J., Poedts, S., Kumari, A., Barata, T., Erdélyi, R. & Kilpua, E. K. J., A&A, 692, A74
41. Solar magnetic flux rope identification with GUITAR: GUI for Tracking and Analysing flux Ropes [3]
    Wagner, Andreas, Price, Daniel J., Bourgeois, Slava, Pomoell, Jens, Poedts, Stefaan & Kilpua, Emilia K. J., Frontiers in Astronomy and Space Sciences, 11, 1383072

2023

1. Extreme-ultraviolet fine structure and variability associated with coronal rain revealed by Solar Orbiter/EUI HRI_EUV and SPICE [22]
   Antolin, P., Dolliou, A., Auchère, F., Chitta, L. P., Parenti, S., Berghmans, D., Aznar Cuadrado, R., Barczynski, K., Gissot, S., Harra, L., Huang, Z., Janvier, M., Kraaikamp, E., Long, D. M., Mandal, S., Peter, H., Rodriguez, L., Schühle, U., Smith, P. J., Solanki, S. K., Stegen, K., Teriaca, L., Verbeeck, C., West, M. J., Zhukov, A. N., Appourchaux, T., Aulanier, G., Buchlin, E., Delmotte, F., Gilles, J. M., Haberreiter, M., Halain, J.-P., Heerlein, K., Hochedez, J.-F., Gyo, M., Poedts, S. & Rochus, P., A&A, 676, A112
2. Exploring the effects of numerical methods and slope limiters in heliospheric modeling [5]
   Baratashvili, Tinatin, Verbeke, Christine, Keppens, Rony & Poedts, Stefaan, Sun and Geosphere, 15, 49
3. First perihelion of EUI on the Solar Orbiter mission [36]
   Berghmans, D., Antolin, P., Auchère, F., Aznar Cuadrado, R., Barczynski, K., Chitta, L. P., Gissot, S., Harra, L., Huang, Z., Janvier, M., Kraaikamp, E., Long, D. M., Mandal, S., Mierla, M., Parenti, S., Peter, H., Rodriguez, L., Schühle, U., Smith, P. J., Solanki, S. K., Stegen, K., Teriaca, L., Verbeeck, C., West, M. J., Zhukov, A. N., Appourchaux, T., Aulanier, G., Buchlin, E., Delmotte, F., Gilles, J. M., Haberreiter, M., Halain, J.-P., Heerlein, K., Hochedez, J.-F., Gyo, M., Poedts, S., Renotte, E. & Rochus, P., A&A, 675, A110
4. The role of plasma β in global coronal models: Bringing balance back to the force [8]
   Brchnelova, M., Kuźma, B., Zhang, F., Lani, A. & Poedts, S., A&A, 676, A83
5. COCONUT-MF: Two-fluid ion-neutral global coronal modelling [6]
   Brchnelova, M., Kuźma, B., Zhang, F., Lani, A. & Poedts, S., A&A, 678, A117
6. Assessing inner boundary conditions for global coronal modeling of solar maxima [6]
   Brchnelova, Michaela, Kuźma, Błażej, Zhang, Fan, Perri, Barbara, Lani, Andrea & Poedts, Stefaan, Sun and Geosphere, 15, 59
7. The East-West Asymmetry of Particle Intensity in Energetic Storm Particle Events [7]
   Ding, Zheyi, Li, Gang, Santa Fe Dueñas, Adolfo, Ebert, Robert W., Wijsen, Nicolas & Poedts, Stefaan, Journal of Geophysical Research (Space Physics), 128, e2023JA031502
8. First Principles Description of Plasma Expansion Using the Expanding Box Model [4]
   Echeverría-Veas, Sebastián, Moya, Pablo S., Lazar, Marian & Poedts, Stefaan, Universe, 9, 448
9. 3D ray tracing solver for communication blackout analysis in atmospheric entry missions [7]
   Giangaspero, Vincent F., Sharma, Vatsalya, Laur, Johannes, Thoemel, Jan, Munafò, Alessandro, Lani, Andrea & Poedts, Stefaan, Computer Physics Communications, 286, 108663
10. Leaky modes in coronal magnetic flux tubes revisited [1]
    Goedbloed, Hans, Keppens, Rony & Poedts, Stefaan, Journal of Plasma Physics, 89, 905890520
11. Thermodynamic and Magnetic Topology Evolution of the X1.0 Flare on 2021 October 28 Simulated by a Data-driven Radiative Magnetohydrodynamic Model [36]
    Guo, J. H., Ni, Y. W., Zhong, Z., Guo, Y., Xia, C., Li, H. T., Poedts, S., Schmieder, B. & Chen, P. F., ApJS, 266, 3
12. Understanding the Lateral Drifting of an Erupting Filament with a Data-constrained Magnetohydrodynamic Simulation [20]
    Guo, J. H., Qiu, Y., Ni, Y. W., Guo, Y., Li, C., Gao, Y. H., Schmieder, B., Poedts, S. & Chen, P. F., ApJ, 956, 119
13. Numerical Calculations of Charging Threshold at GEO Altitudes With Two Temperature Non-Extensive Electrons [0]
    Javed, Saba, Rubab, Nazish, Zaheer, Sadia, Poedts, Stefaan & Jaffer, Ghulam, Space Weather, 21, e2022SW003412
14. Structured type III radio bursts observed in interplanetary space [18]
    Jebaraj, I. C., Magdalenic, J., Krasnoselskikh, V., Krupar, V. & Poedts, S., A&A, 670, A20
15. Monochromatic Two-Fluid Alfvén Waves in the Partially Ionised Solar Chromosphere [7]
    Kraskiewicz, J., Murawski, K., Zhang, F. & Poedts, S., Solar Physics, 298, 11
16. COCONUT, a Novel Fast-converging MHD Model for Solar Corona Simulations. III. Impact of the Preprocessing of the Magnetic Map on the Modeling of the Solar Cycle Activity and Comparison with Observations [29]
    Kuźma, Błażej, Brchnelova, Michaela, Perri, Barbara, Baratashvili, Tinatin, Zhang, Fan, Lani, Andrea & Poedts, Stefaan, ApJ, 942, 31
17. Instability of Langmuir-beam waves: Kappa-distributed electrons [14]
    Lazar, M., López, R. A., Poedts, S. & Shaaban, S. M., Physics of Plasmas, 30, 082106
18. The aperiodic firehose instability of counter-beaming electrons in space plasmas [5]
    Lazar, M., López, R. A., Moya, P. S., Poedts, S. & Shaaban, S. M., A&A, 670, A85
19. Kappa-Distributed Electrons in Solar Outflows: Beam-Plasma Instabilities and Radio Emissions [7]
    Lazar, M., López, R. A., Poedts, S. & Shaaban, S. M., Solar Physics, 298, 72
20. Self-consistent propagation of flux ropes in realistic coronal simulations [27]
    Linan, L., Regnault, F., Perri, B., Brchnelova, M., Kuzma, B., Lani, A., Poedts, S. & Schmieder, B., A&A, 675, A101
21. Rotation and interaction of the CMEs of September 8 and 10, 2014, tested with EUHFORIA [26]
    Maharana, Anwesha, Scolini, Camilla, Schmieder, Brigitte & Poedts, Stefaan, A&A, 675, A136
22. Advancing interplanetary magnetohydrodynamic models through solar energetic particle modelling. Insights from the 2013 March 15 SEP event [4]
    Niemela, A., Wijsen, N., Aran, A., Rodriguez, L., Magdalenic, J. & Poedts, S., A&A, 679, A93
23. Generation of solar chromosphere heating and coronal outflows by two-fluid waves [8]
    Pelekhata, M., Murawski, K. & Poedts, S., A&A, 669, A47
24. Impact of the Solar Activity on the Propagation of ICMEs: Simulations of Hydro, Magnetic and Median ICMEs at the Minimum and Maximum of Activity [0]
    Perri, Barbara, Schmieder, Brigitte, Démoulin, Pascal, Poedts, Stefaan & Regnault, Florian, ApJ, 955, 50
25. COCONUT, a Novel Fast-converging MHD Model for Solar Corona Simulations. II. Assessing the Impact of the Input Magnetic Map on Space-weather Forecasting at Minimum of Activity [39]
    Perri, Barbara, Kuźma, Błażej, Brchnelova, Michaela, Baratashvili, Tinatin, Zhang, Fan, Leitner, Peter, Lani, Andrea & Poedts, Stefaan, ApJ, 943, 124
26. The impact of quantized magnetic pressure on the stimulated Brillouin scattering of electromagnetic waves [2]
    Rozina, Ch, Maroosh, A., Poedts, S. & Shah, H. A., Physica Scripta, 98, 105601
27. Rayleigh-Taylor instability in an adiabatic-radiative rare plasma [3]
    Rozina, Ch, Sania, B., Poedts, S., Ali, S. & Maryam, N., Physica Scripta, 98, 045616
28. Signatures of quantized magnetic field on the nonlinear Landau damping of transverse electromagnetic waves [2]
    Rozina, Ch, Asma, A., Poedts, S., Ali, S. & Shah, H. A., Physica Scripta, 98, 095601
29. How Nonlinearity Changes Different Parameters in the Solar Corona [2]
    Sabri, S., Poedts, S. & Ebadi, H., ApJ, 944, 72
30. Reductive perturbation method in magnetized plasma and role of negative ions [7]
    Saleem, H., Shan, Shaukat Ali & Poedts, S., Physics of Plasmas, 30, 122111
31. Characteristic Scales of Complexity and Coherence within Interplanetary Coronal Mass Ejections: Insights from Spacecraft Swarms in Global Heliospheric Simulations [17]
    Scolini, Camilla, Winslow, Réka M., Lugaz, Noé & Poedts, Stefaan, ApJ, 944, 46
32. The automatic identification and tracking of coronal flux ropes. I. Footpoints and fluxes [8]
    Wagner, A., Kilpua, E. K. J., Sarkar, R., Price, D. J., Kumari, A., Daei, F., Pomoell, J. & Poedts, S., A&A, 677, A81
33. Review of Solar Energetic Particle Prediction Models [114]
    Whitman, Kathryn, Egeland, Ricky, Richardson, Ian G., Allison, Clayton, Quinn, Philip, Barzilla, Janet, Kitiashvili, Irina, Sadykov, Viacheslav, Bain, Hazel M., Dierckxsens, Mark, Mays, M. Leila, Tadesse, Tilaye, Lee, Kerry T., Semones, Edward, Luhmann, Janet G., Núñez, Marlon, White, Stephen M., Kahler, Stephen W., Ling, Alan G., Smart, Don F., Shea, Margaret A., Tenishev, Valeriy, Boubrahimi, Soukaina F., Aydin, Berkay, Martens, Petrus, Angryk, Rafal, Marsh, Michael S., Dalla, Silvia, Crosby, Norma, Schwadron, Nathan A., Kozarev, Kamen, Gorby, Matthew, Young, Matthew A., Laurenza, Monica, Cliver, Edward W., Alberti, Tommaso, Stumpo, Mirko, Benella, Simone, Papaioannou, Athanasios, Anastasiadis, Anastasios, Sandberg, Ingmar, Georgoulis, Manolis K., Ji, Anli, Kempton, Dustin, Pandey, Chetraj, Li, Gang, Hu, Junxiang, Zank, Gary P., Lavasa, Eleni, Giannopoulos, Giorgos, Falconer, David, Kadadi, Yash, Fernandes, Ian, Dayeh, Maher A., Muñoz-Jaramillo, Andrés, Chatterjee, Subhamoy, Moreland, Kimberly D., Sokolov, Igor V., Roussev, Ilia I., Taktakishvili, Aleksandre, Effenberger, Frederic, Gombosi, Tamas, Huang, Zhenguang, Zhao, Lulu, Wijsen, Nicolas, Aran, Angels, Poedts, Stefaan, Kouloumvakos, Athanasios, Paassilta, Miikka, Vainio, Rami, Belov, Anatoly, Eroshenko, Eugenia A., Abunina, Maria A., Abunin, Artem A., Balch, Christopher C., Malandraki, Olga, Karavolos, Michalis, Heber, Bernd, Labrenz, Johannes, Kühl, Patrick, Kosovichev, Alexander G., Oria, Vincent, Nita, Gelu M., Illarionov, Egor, O'Keefe, Patrick M., Jiang, Yucheng, Fereira, Sheldon H., Ali, Aatiya, Paouris, Evangelos, Aminalragia-Giamini, Sigiava, Jiggens, Piers, Jin, Meng, Lee, Christina O., Palmerio, Erika, Bruno, Alessandro, Kasapis, Spiridon, Wang, Xiantong, Chen, Yang, Sanahuja, Blai, Lario, David, Jacobs, Carla, Strauss, Du Toit, Steyn, Ruhann, van den Berg, Jabus, Swalwell, Bill, Waterfall, Charlotte, Nedal, Mohamed, Miteva, Rositsa, Dechev, Momchil, Zucca, Pietro, Engell, Alec, Maze, Brianna, Farmer, Harold, Kerber, Thuha, Barnett, Ben, Loomis, Jeremy, Grey, Nathan, Thompson, Barbara J., Linker, Jon A., Caplan, Ronald M., Downs, Cooper, Török, Tibor, Lionello, Roberto, Titov, Viacheslav, Zhang, Ming & Hosseinzadeh, Pouya, Advances in Space Research, 72, 5161
34. On the Seed Population of Solar Energetic Particles in the Inner Heliosphere [26]
    Wijsen, N., Li, G., Ding, Z., Lario, D., Poedts, S., Filwett, R. J., Allen, R. C. & Dayeh, M. A., Journal of Geophysical Research (Space Physics), 128, e2022JA031203
35. The Effect of the Ambient Solar Wind Medium on a CME-driven Shock and the Associated Gradual Solar Energetic Particle Event [30]
    Wijsen, Nicolas, Lario, David, Sánchez-Cano, Beatriz, Jebaraj, Immanuel C., Dresing, Nina, Richardson, Ian G., Aran, Angels, Kouloumvakos, Athanasios, Ding, Zheyi, Niemela, Antonio, Palmerio, Erika, Carcaboso, Fernando, Vainio, Rami, Afanasiev, Alexandr, Pinto, Marco, Pacheco, Daniel, Poedts, Stefaan & Heyner, Daniel, ApJ, 950, 172
36. Interplay between Anisotropy- and Skewness-driven Whistler Instabilities in the Solar Wind under the Core-Strahlo Model [5]
    Zenteno-Quinteros, Bea, Moya, Pablo S., Lazar, Marian, Viñas, Adolfo F. & Poedts, Stefaan, ApJ, 954, 184

2022

1. Quasi-electrostatic instability in non-gyrotropic tri-ion electron plasma [4]
   Arshad, Kashif, Poedts, Stefaan & Dahshan, Alaa, AIP Advances, 12, 105319
2. Improving CME evolution and arrival predictions with AMR and grid stretching in Icarus [19]
   Baratashvili, T., Verbeke, C., Wijsen, N. & Poedts, S., A&A, 667, A133
3. r-adaptive algorithms for supersonic flows with high-order Flux Reconstruction methods [3]
   Ben Ameur, Firas, Balis, Joachim, Vandenhoeck, Ray, Lani, Andrea & Poedts, Stefaan, Computer Physics Communications, 276, 108373
4. Effects of mesh topology on MHD solution features in coronal simulations [13]
   Brchnelova, M., Zhang, F., Leitner, P., Perri, B., Lani, A. & Poedts, S., Journal of Plasma Physics, 88, 905880205
5. To E or Not to E : Numerical Nuances of Global Coronal Models [20]
   Brchnelova, Michaela, Kuźma, Błażej, Perri, Barbara, Lani, Andrea & Poedts, Stefaan, ApJS, 263, 18
6. Modeling the 2020 November 29 solar energetic particle event using EUHFORIA and iPATH models [22]
   Ding, Zheyi, Wijsen, Nicolas, Li, Gang & Poedts, Stefaan, A&A, 668, A71
7. How the area of solar coronal holes affects the properties of high-speed solar wind streams near Earth: An analytical model [21]
   Hofmeister, Stefan J., Asvestari, Eleanna, Guo, Jingnan, Heidrich-Meisner, Verena, Heinemann, Stephan G., Magdalenic, Jasmina, Poedts, Stefaan, Samara, Evangelia, Temmer, Manuela, Vennerstrom, Susanne, Veronig, Astrid, Vršnak, Bojan & Wimmer-Schweingruber, Robert, A&A, 659, A190
8. Analysis of Voyager 1 and Voyager 2 in situ CME observations [2]
   Hosteaux, Skralan, Rodiguez, Luciano & Poedts, Stefaan, Advances in Space Research, 70, 1684
9. Toward a Realistic Evaluation of Transport Coefficients in Non-equilibrium Space Plasmas [7]
   Husidic, Edin, Scherer, Klaus, Lazar, Marian, Fichtner, Horst & Poedts, Stefaan, ApJ, 927, 159
10. Successive Interacting Coronal Mass Ejections: How to Create a Perfect Storm [28]
    Koehn, G. J., Desai, R. T., Davies, E. E., Forsyth, R. J., Eastwood, J. P. & Poedts, S., ApJ, 941, 139
11. Influence of Large-scale Interplanetary Structures on the Propagation of Solar Energetic Particles: The Multispacecraft Event on 2021 October 9 [25]
    Lario, D., Wijsen, N., Kwon, R. Y., Sánchez-Cano, B., Richardson, I. G., Pacheco, D., Palmerio, E., Stevens, M. L., Szabo, A., Heyner, D., Dresing, N., Gómez-Herrero, R., Carcaboso, F., Aran, A., Afanasiev, A., Vainio, R., Riihonen, E., Poedts, S., Brüden, M., Xu, Z. G. & Kollhoff, A., ApJ, 934, 55
12. About the effects of solar wind suprathermal electrons on electrostatic waves [9]
    Lazar, M., Shaaban, S. M., López, R. A. & Poedts, S., Astrophysics and Space Science, 367, 104
13. Temperature anisotropy instabilities stimulated by the solar wind suprathermal populations [23]
    Lazar, Marian, López, R. A., Shaaban, Shaaban Mohammed, Poedts, Stefaan, Yoon, Peter Haesung & Fichtner, Horst, Frontiers in Astronomy and Space Sciences, 8, 249
14. Observation from Earth of an atypical cloud system in the upper Martian atmosphere [3]
    Lilensten, J., Dauvergne, J. L., Pellier, C., Delcroix, M., Beaudoin, E., Vincendon, M., Kraaikamp, E., Bertrand, G., Foster, C., Go, C., Kardasis, E., Pace, A., Peach, D., Wesley, A., Samara, E., Poedts, S. & Colas, F., A&A, 661, A127
15. Mixing the Solar Wind Proton and Electron Scales. Theory and 2D-PIC Simulations of Firehose Instability [11]
    López, R. A., Micera, A., Lazar, M., Poedts, S., Lapenta, G., Zhukov, A. N., Boella, E. & Shaaban, S. M., ApJ, 930, 158
16. Implementation and validation of the FRi3D flux rope model in EUHFORIA [44]
    Maharana, Anwesha, Isavnin, Alexey, Scolini, Camilla, Wijsen, Nicolas, Rodriguez, Luciano, Mierla, Marilena, Magdalenić, Jasmina & Poedts, Stefaan, Advances in Space Research, 70, 1641
17. Novel features of electromagnetic waves in an isotropic degenerate electron-ion plasma [1]
    Maryam, P., Rozina, Ch, Ali, S., Shah, H. A. & Poedts, S., Plasma Physics and Controlled Fusion, 64, 025006
18. Comparing the Counter-beaming and Temperature Anisotropy Driven Aperiodic Electron Firehose Instabilities in Collisionless Plasma Environments [3]
    Moya, Pablo S., López, Rodrigo A., Lazar, Marian, Poedts, Stefaan & Shaaban, Shaaban M., ApJ, 937, 49
19. Two-fluid numerical model of chromospheric heating and plasma outflows in a quiet-Sun [15]
    Murawski, K., Musielak, Z. E., Poedts, S., Srivastava, A. K. & Kadowaki, L., Astrophysics and Space Science, 367, 111
20. Impulsively generated two-fluid magnetoacoustic-gravity waves: Solar chromosphere heating and plasma outflows [4]
    Niedziela, R., Murawski, K., Kadowaki, L., Zaqarashvili, T. & Poedts, S., A&A, 668, A32
21. COCONUT, a Novel Fast-converging MHD Model for Solar Corona Simulations: I. Benchmarking and Optimization of Polytropic Solutions [55]
    Perri, Barbara, Leitner, Peter, Brchnelova, Michaela, Baratashvili, Tinatin, Kuźma, Błażej, Zhang, Fan, Lani, Andrea & Poedts, Stefaan, ApJ, 936, 19
22. The European Solar Telescope [82]
    Quintero Noda, C., Schlichenmaier, R., Bellot Rubio, L. R., Löfdahl, M. G., Khomenko, E., Jurčák, J., Leenaarts, J., Kuckein, C., González Manrique, S. J., Gunár, S., Nelson, C. J., de la Cruz Rodríguez, J., Tziotziou, K., Tsiropoula, G., Aulanier, G., Aboudarham, J., Allegri, D., Alsina Ballester, E., Amans, J. P., Asensio Ramos, A., Bailén, F. J., Balaguer, M., Baldini, V., Balthasar, H., Barata, T., Barczynski, K., Barreto Cabrera, M., Baur, A., Béchet, C., Beck, C., Belío-Asín, M., Bello-González, N., Belluzzi, L., Bentley, R. D., Berdyugina, S. V., Berghmans, D., Berlicki, A., Berrilli, F., Berkefeld, T., Bettonvil, F., Bianda, M., Bienes Pérez, J., Bonaque-González, S., Brajša, R., Bommier, V., Bourdin, P.-A., Burgos Martín, J., Calchetti, D., Calcines, A., Calvo Tovar, J., Campbell, R. J., Carballo-Martín, Y., Carbone, V., Carlin, E. S., Carlsson, M., Castro López, J., Cavaller, L., Cavallini, F., Cauzzi, G., Cecconi, M., Chulani, H. M., Cirami, R., Consolini, G., Coretti, I., Cosentino, R., Cózar-Castellano, J., Dalmasse, K., Danilovic, S., De Juan Ovelar, M., Del Moro, D., del Pino Alemán, T., del Toro Iniesta, J. C., Denker, C., Dhara, S. K., Di Marcantonio, P., Díaz Baso, C. J., Diercke, A., Dineva, E., Díaz-García, J. J., Doerr, H.-P., Doyle, G., Erdelyi, R., Ermolli, I., Escobar Rodríguez, A., Esteban Pozuelo, S., Faurobert, M., Felipe, T., Feller, A., Feijoo Amoedo, N., Femenía Castellá, B., Fernandes, J., Ferro Rodríguez, I., Figueroa, I., Fletcher, L., Franco Ordovas, A., Gafeira, R., Gardenghi, R., Gelly, B., Giorgi, F., Gisler, D., Giovannelli, L., González, F., González, J. B., González-Cava, J. M., González García, M., Gömöry, P., Gracia, F., Grauf, B., Greco, V., Grivel, C., Guerreiro, N., Guglielmino, S. L., Hammerschlag, R., Hanslmeier, A., Hansteen, V., Heinzel, P., Hernández-Delgado, A., Hernández Suárez, E., Hidalgo, S. L., Hill, F., Hizberger, J., Hofmeister, S., Jägers, A., Janett, G., Jarolim, R., Jess, D., Jiménez Mejías, D., Jolissaint, L., Kamlah, R., Kapitán, J., Kašparová, J., Keller, C. U., Kentischer, T., Kiselman, D., Kleint, L., Klvana, M., Kontogiannis, I., Krishnappa, N., Kučera, A., Labrosse, N., Lagg, A., Landi Degl'Innocenti, E., Langlois, M., Lafon, M., Laforgue, D., Le Men, C., Lepori, B., Lepreti, F., Lindberg, B., Lilje, P. B., López Ariste, A., López Fernández, V. A., López Jiménez, A. C., López López, R., Manso Sainz, R., Marassi, A., Marco de la Rosa, J., Marino, J., Marrero, J., Martín, A., Martín Gálvez, A., Martín Hernando, Y., Masciadri, E., Martínez González, M., Matta-Gómez, A., Mato, A., Mathioudakis, M., Matthews, S., Mein, P., Merlos García, F., Moity, J., Montilla, I., Molinaro, M., Molodij, G., Montoya, L. M., Munari, M., Murabito, M., Núñez Cagigal, M., Oliviero, M., Orozco Suárez, D., Ortiz, A., Padilla-Hernández, C., Paéz Mañá, E., Paletou, F., Pancorbo, J., Pastor Cañedo, A., Pastor Yabar, A., Peat, A. W., Pedichini, F., Peixinho, N., Peñate, J., Pérez de Taoro, A., Peter, H., Petrovay, K., Piazzesi, R., Pietropaolo, E., Pleier, O., Poedts, S., Pötzi, W., Podladchikova, T., Prieto, G., Quintero Nehrkorn, J., Ramelli, R., Ramos Sapena, Y., Rasilla, J. L., Reardon, K., Rebolo, R., Regalado Olivares, S., Reyes García-Talavera, M., Riethmüller, T. L., Rimmele, T., Rodríguez Delgado, H., Rodríguez González, N., Rodríguez-Losada, J. A., Rodríguez Ramos, L. F., Romano, P., Roth, M., Rouppe van der Voort, L., Rudawy, P., Ruiz de Galarreta, C., Rybák, J., Salvade, A., Sánchez-Capuchino, J., Sánchez Rodríguez, M. L., Sangiorgi, M., Sayède, F., Scharmer, G., Scheiffelen, T., Schmidt, W., Schmieder, B., Scirè, C., Scuderi, S., Siegel, B., Sigwarth, M., Simões, P. J. A., Snik, F., Sliepen, G., Sobotka, M., Socas-Navarro, H., Sola La Serna, P., Solanki, S. K., Soler Trujillo, M., Soltau, D., Sordini, A., Sosa Méndez, A., Stangalini, M., Steiner, O., Stenflo, J. O., Štěpán, J., Strassmeier, K. G., Sudar, D., Suematsu, Y., Sütterlin, P., Tallon, M., Temmer, M., Tenegi, F., Tritschler, A., Trujillo Bueno, J., Turchi, A., Utz, D., van Harten, G., van Noort, M., van Werkhoven, T., Vansintjan, R., Vaz Cedillo, J. J., Vega Reyes, N., Verma, M., Veronig, A. M., Viavattene, G., Vitas, N., Vögler, A., von der Lühe, O., Volkmer, R., Waldmann, T. A., Walton, D., Wisniewska, A., Zeman, J., Zeuner, F., Zhang, L. Q., Zuccarello, F. & Collados, M., A&A, 666, A21
23. Comparing the Heliospheric Cataloging, Analysis, and Techniques Service (HELCATS) Manual and Automatic Catalogues of Coronal Mass Ejections Using Solar Terrestrial Relations Observatory/Heliospheric Imager (STEREO/HI) Data [6]
    Rodriguez, L., Barnes, D., Hosteaux, S., Davies, J. A., Willems, S., Pant, V., Harrison, R. A., Berghmans, D., Bothmer, V., Eastwood, J. P., Gallagher, P. T., Kilpua, E. K. J., Magdalenic, J., Mierla, M., Möstl, C., Rouillard, A. P., Odstrčil, D. & Poedts, S., Solar Physics, 297, 23
24. Self-similarity for astrophysical MHD transients revisited [0]
    Rogava, Andria, Poedts, Stefaan & Dadiani, Ekaterine, Advances in Space Research, 69, 474
25. Propagation of the Alfvén Wave and Induced Perturbations in the Vicinity of a 3D Proper Magnetic Null Point [6]
    Sabri, S., Ebadi, H. & Poedts, S., ApJ, 924, 126
26. Dynamic Time Warping as a Means of Assessing Solar Wind Time Series [30]
    Samara, E., Laperre, B., Kieokaew, R., Temmer, M., Verbeke, C., Rodriguez, L., Magdalenić, J. & Poedts, S., ApJ, 927, 187
27. Influence of coronal hole morphology on the solar wind speed at Earth [10]
    Samara, Evangelia, Magdalenić, Jasmina, Rodriguez, Luciano, Heinemann, Stephan G., Georgoulis, Manolis K., Hofmeister, Stefan J. & Poedts, Stefaan, A&A, 662, A68
28. Categorization model of moving small-scale intensity enhancements in solar active regions [1]
    Shergelashvili, B. M., Philishvili, E., Buitendag, S., Poedts, S. & Khodachenko, M., A&A, 662, A30
29. Study of the propagation, in situ signatures, and geoeffectiveness of shear-induced coronal mass ejections in different solar winds [10]
    Talpeanu, D.-C., Poedts, S., D'Huys, E. & Mierla, M., A&A, 658, A56
30. Interaction of coronal mass ejections and the solar wind. A force analysis [6]
    Talpeanu, D.-C., Poedts, S., D'Huys, E., Mierla, M. & Richardson, I. G., A&A, 663, A32
31. ICARUS, a new inner heliospheric model with a flexible grid [33]
    Verbeke, C., Baratashvili, T. & Poedts, S., A&A, 662, A50
32. Over-expansion of coronal mass ejections modelled using 3D MHD EUHFORIA simulations [15]
    Verbeke, Christine, Schmieder, Brigitte, Démoulin, Pascal, Dasso, Sergio, Grison, Benjamin, Samara, Evangelia, Scolini, Camilla & Poedts, Stefaan, Advances in Space Research, 70, 1663
33. Observation-based modelling of the energetic storm particle event of 14 July 2012 [37]
    Wijsen, N., Aran, A., Scolini, C., Lario, D., Afanasiev, A., Vainio, R., Sanahuja, B., Pomoell, J. & Poedts, S., A&A, 659, A187
34. On the importance of investigating CME complexity evolution during interplanetary propagation [11]
    Winslow, Réka M., Scolini, Camilla, Jian, Lan K., Nieves-Chinchilla, Teresa, Temmer, Manuela, Carcaboso, Fernando, Schmieder, Brigitte, Poedts, Stefaan, Lynch, Benjamin J., Wood, Brian E., Palmerio, Erika, Lugaz, Noé, Farrugia, Charles J., Lee, Christina O., Davies, Emma E., Regnault, Florian, Salman, Tarik M., Török, Tibor, Al-Haddad, Nada, Vourlidas, Angelos, Manchester, Ward B., Jin, Meng, Lavraud, Benoit & Galvin, Antoinette B., Frontiers in Astronomy and Space Sciences, 9, 422
35. Broadband Electrostatic Waves near the Lower-hybrid Frequency in the Near-Sun Solar Wind Observed by the Parker Solar Probe [7]
    Zhao, Jinsong, Malaspina, David M., Dudok de Wit, T., Pierrard, Viviane, Voitenko, Yuriy, Lapenta, Giovanni, Poedts, Stefaan, Bale, Stuart D., Kasper, Justin C., Larson, Davin, Livi, Roberto & Whittlesey, Phyllis, ApJ, 938, L21

2021

1. Evidence for local particle acceleration in the first recurrent galactic cosmic ray depression observed by Solar Orbiter. The ion event on 19 June 2020 [6]
   Aran, A., Pacheco, D., Laurenza, M., Wijsen, N., Lario, D., Benella, S., Richardson, I. G., Samara, E., Freiherr von Forstner, J. L., Sanahuja, B., Rodriguez, L., Balmaceda, L., Espinosa Lara, F., Gómez-Herrero, R., Steinvall, K., Vecchio, A., Krupar, V., Poedts, S., Allen, R. C., Andrews, G. B., Angelini, V., Berger, L., Berghmans, D., Boden, S., Böttcher, S. I., Carcaboso, F., Cernuda, I., De Marco, R., Eldrum, S., Evans, V., Fedorov, A., Hayes, J., Ho, G. C., Horbury, T. S., Janitzek, N. P., Khotyaintsev, Yu. V., Kollhoff, A., Kühl, P., Kulkarni, S. R., Lees, W. J., Louarn, P., Magdalenic, J., Maksimovic, M., Malandraki, O., Martínez, A., Mason, G. M., Martín, C., O'Brien, H., Owen, C., Parra, P., Prieto Mateo, M., Ravanbakhsh, A., Rodriguez-Pacheco, J., Rodriguez Polo, O., Sánchez Prieto, S., Schlemm, C. E., Seifert, H., Terasa, J. C., Tyagi, K., Verbeeck, C., Wimmer-Schweingruber, R. F., Xu, Z. G., Yedla, M. K. & Zhukov, A. N., A&A, 656, L10
2. Modelling a multi-spacecraft coronal mass ejection encounter with EUHFORIA [33]
   Asvestari, E., Pomoell, J., Kilpua, E., Good, S., Chatzistergos, T., Temmer, M., Palmerio, E., Poedts, S. & Magdalenic, J., A&A, 652, A27
3. Over-expansion of a coronal mass ejection generates sub-Alfvénic plasma conditions in the solar wind at Earth [9]
   Chané, E., Schmieder, B., Dasso, S., Verbeke, C., Grison, B., Démoulin, P. & Poedts, S., A&A, 647, A149
4. Eigenspectra of solar active region long-period oscillations [4]
   Dumbadze, G., Shergelashvili, B. M., Poedts, S., Zaqarashvili, T. V., Khodachenko, M. & De Causmaecker, P., A&A, 653, A39
5. Analysis of Deformation and Erosion during CME Evolution [7]
   Hosteaux, Skralan, Chané, Emmanuel & Poedts, Stefaan, Geosciences, 11, 314
6. Transport coefficients enhanced by suprathermal particles in nonequilibrium heliospheric plasmas [11]
   Husidic, E., Lazar, M., Fichtner, H., Scherer, K. & Poedts, S., A&A, 654, A99
7. Generation of interplanetary type II radio emission [33]
   Jebaraj, I. C., Kouloumvakos, A., Magdalenic, J., Rouillard, A. P., Mann, G., Krupar, V. & Poedts, S., A&A, 654, A64
8. Modelling the propagation of solar disturbances to Earth for the EU H2020 SafeSpace project [0]
   Kieokaew, Rungployphan, Ferreira Pinto, Rui, Lavraud, Benoit, Brunet, Antoine, Bernoux, Guillerme, Samara, Evangelia, Poedts, Stefaan, Génot, Vincent, Rouillard, Alexis, Bourdarie, Sebastien, Grison, Benjamin, Souček, Jan & Daglis, Ioannis, essoar.10509816
9. 3D numerical simulations of propagating two-fluid, torsional Alfvén waves and heating of a partially ionized solar chromosphere [9]
   Kuźma, B., Murawski, K. & Poedts, S., MNRAS, 506, 989
10. Spatial variation in the periods of ion and neutral waves in a solar magnetic arcade [6]
    Kuźma, B., Murawski, K., Musielak, Z. E., Poedts, S. & Wójcik, D., A&A, 652, A88
11. Quo vadis, European Space Weather community? [4]
    Lilensten, Jean, Dumbović, Mateja, Spogli, Luca, Belehaki, Anna, Van der Linden, Ronald, Poedts, Stefaan, Barata, Teresa, Bisi, Mario M., Cessateur, Gaël, De Donder, Erwin, Guerrero, Antonio, Kilpua, Emilia, Korsos, Marianna B., Pinto, Rui F., Temmer, Manuela, Tsagouri, Ioanna, Urbář, Jaroslav & Zuccarello, Francesca, Journal of Space Weather and Space Climate, 11, 26
12. Advanced Numerical Tools for Studying Waves and Instabilities in Kappa Distributed Plasmas [0]
    López, Rodrigo A., Moya, Pablo S., Shaaban, Shaaban M., Lazar, Marian, Yoon, Peter H. & Poedts, Stefaan, Kappa Distributions; From Observational Evidences via Controversial Predictions to a Consistent Theory of Nonequilibrium Plasmas (Editors: Lazar, Marian & Fichtner, Horst), Astrophysics and Space Science Library, 464, p. 163
13. Toward a general quasi-linear approach for the instabilities of bi-Kappa plasmas. Whistler instability [21]
    Moya, P. S., Lazar, M. & Poedts, S., Plasma Physics and Controlled Fusion, 63, 025011
14. Thermal conduction effects on formation of chromospheric solar tadpole-like jets [5]
    Navarro, Anamaría, Lora-Clavijo, F. D., Murawski, K. & Poedts, Stefaan, MNRAS, 500, 3329
15. Chromospheric heating and generation of plasma outflows by impulsively generated two-fluid magnetoacoustic waves [16]
    Niedziela, R., Murawski, K. & Poedts, S., A&A, 652, A124
16. Solar chromosphere heating and generation of plasma outflows by impulsively generated two-fluid Alfvén waves [14]
    Pelekhata, M., Murawski, K. & Poedts, S., A&A, 652, A114
17. Case study on the identification and classification of small-scale flow patterns in flaring active region [2]
    Philishvili, E., Shergelashvili, B. M., Buitendag, S., Raes, J., Poedts, S. & Khodachenko, M. L., A&A, 645, A52
18. The Virtual Space Weather Modeling Centre - Part 3 [0]
    Poedts, Stefaan, essoar.10505657
19. Plasma Flow Generation due to the Nonlinear Alfvén Wave Propagation around a 3D Magnetic Null Point [5]
    Sabri, S., Ebadi, H. & Poedts, S., ApJ, 922, 123
20. Implementing the MULTI-VP coronal model in EUHFORIA: Test case results and comparisons with the WSA coronal model [36]
    Samara, E., Pinto, R. F., Magdalenić, J., Wijsen, N., Jerčić, V., Scolini, C., Jebaraj, I. C., Rodriguez, L. & Poedts, S., A&A, 648, A35
21. Exploring the radial evolution of interplanetary coronal mass ejections using EUHFORIA [25]
    Scolini, C., Dasso, S., Rodriguez, L., Zhukov, A. N. & Poedts, S., A&A, 649, A69
22. Evolution of Interplanetary Coronal Mass Ejection Complexity: A Numerical Study through a Swarm of Simulated Spacecraft [24]
    Scolini, Camilla, Winslow, Reka M., Lugaz, Noé & Poedts, Stefaan, ApJ, 916, L15
23. Advanced Interpretation of Waves and Instabilities in Space Plasmas [5]
    Shaaban, Shaaban M., Lazar, Marian, López, Rodrigo A., Yoon, Peter H. & Poedts, Stefaan, Kappa Distributions; From Observational Evidences via Controversial Predictions to a Consistent Theory of Nonequilibrium Plasmas (Editors: Lazar, Marian & Fichtner, Horst), Astrophysics and Space Science Library, 464, p. 185
24. Proton-Alpha Drift Instability of Electromagnetic Ion-Cyclotron Modes: Quasilinear Development [2]
    Shaaban, Shaaban M., Lazar, Marian, Yoon, Peter H., Poedts, Stefaan & López, Rodrigo A., Physics, 3, 1175
25. A Self-consistent Simulation of Proton Acceleration and Transport Near a High-speed Solar Wind Stream [36]
    Wijsen, Nicolas, Samara, Evangelia, Aran, Àngels, Lario, David, Pomoell, Jens & Poedts, Stefaan, ApJ, 908, L26
26. Two-fluid Modeling of Acoustic Wave Propagation in Gravitationally Stratified Isothermal Media [27]
    Zhang, Fan, Poedts, Stefaan, Lani, Andrea, Kuźma, Błażej & Murawski, Kris, ApJ, 911, 119

2020

1. Twisted waves in symmetric and asymmetric bi-ion kappa-distributed plasmas [11]
   Arshad, Kashif & Poedts, S., Physics of Plasmas, 27, 122904
2. Twisted waves in symmetric and asymmetric bi-ion Kappa-distributed plasmas [0]
   Arshad, kashif & Poedts, S., essoar.10504770
3. The impact of coronal hole characteristics and solar cycle activity in reconstructing coronal holes with EUHFORIA [4]
   Asvestari, E., Heinemann, S. G., Temmer, M., Pomoell, J., Kilpua, E., Magdalenic, J. & Poedts, S., Journal of Physics Conference Series, Journal of Physics Conference Series, 1548, p. 012004
4. On the Dependency between the Peak Velocity of High-speed Solar Wind Streams near Earth and the Area of Their Solar Source Coronal Holes [15]
   Hofmeister, Stefan J., Veronig, Astrid M., Poedts, Stefaan, Samara, Evangelia & Magdalenic, Jasmina, ApJ, 897, L17
5. Using radio triangulation to understand the origin of two subsequent type II radio bursts [31]
   Jebaraj, I. C., Magdalenić, J., Podladchikova, T., Scolini, C., Pomoell, J., Veronig, A. M., Dissauer, K., Krupar, V., Kilpua, E. K. J. & Poedts, S., A&A, 639, A56
6. Solar Flare Prediction Using Magnetic Field Diagnostics above the Photosphere [34]
   Korsós, M. B., Georgoulis, M. K., Gyenge, N., Bisoi, S. K., Yu, S., Poedts, S., Nelson, C. J., Liu, J., Yan, Y. & Erdélyi, R., ApJ, 896, 119
7. Numerical simulations of the lower solar atmosphere heating by two-fluid nonlinear Alfvén waves [18]
   Kuźma, B., Wójcik, D., Murawski, K., Yuan, D. & Poedts, S., A&A, 639, A45
8. Characteristics of solar wind suprathermal halo electrons [25]
   Lazar, M., Pierrard, V., Poedts, S. & Fichtner, H., A&A, 642, A130
9. Alternative High-plasma Beta Regimes of Electron Heat-flux Instabilities in the Solar Wind [47]
   López, R. A., Lazar, M., Shaaban, S. M., Poedts, S. & Moya, P. S., ApJ, 900, L25
10. A firehose-like aperiodic instability of counter-beaming electron plasmas [3]
    López, R. A., Lazar, M., Shaaban, S. M., Poedts, S. & Moya, P. S., Plasma Physics and Controlled Fusion, 62, 075006
11. Determination of the solar rotation parameters via orthogonal polynomials [4]
    Mdzinarishvili, T. G., Shergelashvili, B. M., Japaridze, D. R., Chargeishvili, B. B., Kosovichev, A. G. & Poedts, S., Advances in Space Research, 65, 1843
12. Domain of Influence analysis: implications for Data Assimilation in space weather forecasting [3]
    Millas, Dimitrios, Innocenti, Maria Elena, Laperre, Brecht, Raeder, Joachim, Poedts, Stefaan & Lapenta, Giovanni, Frontiers in Astronomy and Space Sciences, 7, 73
13. Feasibility of Ion-cyclotron Resonant Heating in the Solar Wind [7]
    Navarro, Roberto E., Muñoz, Víctor, Valdivia, Juan A. & Moya, Pablo S., ApJ, 898, L9
14. The Virtual Space Weather Modelling Centre [19]
    Poedts, Stefaan, Kochanov, Andrey, Lani, Andrea, Scolini, Camilla, Verbeke, Christine, Hosteaux, Skralan, Chané, Emmanuel, Deconinck, Herman, Mihalache, Nicolae, Diet, Fabian, Heynderickx, Daniel, De Keyser, Johan, De Donder, Erwin, Crosby, Norma B., Echim, Marius, Rodriguez, Luciano, Vansintjan, Robbe, Verstringe, Freek, Mampaey, Benjamin, Horne, Richard, Glauert, Sarah, Jiggens, Piers, Keil, Ralf, Glover, Alexi, Deprez, Grégoire & Luntama, Juha-Pekka, Journal of Space Weather and Space Climate, 10, 14
15. EUropean Heliospheric FORecasting Information Asset 2.0 [41]
    Poedts, Stefaan, Lani, Andrea, Scolini, Camilla, Verbeke, Christine, Wijsen, Nicolas, Lapenta, Giovanni, Laperre, Brecht, Millas, Dimitrios, Innocenti, Maria Elena, Chané, Emmanuel, Baratashvili, Tinatin, Samara, Evangelia, Van der Linden, Ronald, Rodriguez, Luciano, Vanlommel, Petra, Vainio, Rami, Afanasiev, Alexandr, Kilpua, Emilia, Pomoell, Jens, Sarkar, Ranadeep, Aran, Angels, Sanahuja, Blai, Paredes, Josep M., Clarke, Ellen, Thomson, Alan, Rouilard, Alexis, Pinto, Rui F., Marchaudon, Aurélie, Blelly, Pierre-Louis, Gorce, Blandine, Plotnikov, Illya, Kouloumvakos, Athanasis, Heber, Bernd, Herbst, Konstantin, Kochanov, Andrey, Raeder, Joachim & Depauw, Jan, Journal of Space Weather and Space Climate, 10, 57
16. Electromagnetic instabilities of low-beta alpha/proton beams in space plasmas [2]
    Rehman, M. A., Shaaban, S. M., Yoon, P. H., Lazar, M. & Poedts, S., Astrophysics and Space Science, 365, 107
17. Plasmoids and Resulting Blobs due to the Interaction of Magnetoacoustic Waves with a 2.5D Magnetic Null Point [7]
    Sabri, S., Ebadi, H. & Poedts, S., ApJ, 902, 11
18. How Alfvén waves induce compressive flows in the neighborhood of a 2.5D magnetic null-point [11]
    Sabri, S., Farahani, S. Vasheghani, Ebadi, H. & Poedts, S., Scientific Reports, 10, 15603
19. Low Geo-Effectiveness of Fast Halo CMEs Related to the 12 X-Class Flares in 2002 [12]
    Schmieder, B., Kim, R.-S., Grison, B., Bocchialini, K., Kwon, R.-Y., Poedts, S. & Démoulin, P., Journal of Geophysical Research (Space Physics), 125, e27529
20. Improving Predictions of High-Latitude Coronal Mass Ejections Throughout the Heliosphere [10]
    Scolini, C., Chané, E., Pomoell, J., Rodriguez, L. & Poedts, S., Space Weather, 18, e02246
21. CME-CME Interactions as Sources of CME Geoeffectiveness: The Formation of the Complex Ejecta and Intense Geomagnetic Storm in 2017 Early September [138]
    Scolini, Camilla, Chané, Emmanuel, Temmer, Manuela, Kilpua, Emilia K. J., Dissauer, Karin, Veronig, Astrid M., Palmerio, Erika, Pomoell, Jens, Dumbović, Mateja, Guo, Jingnan, Rodriguez, Luciano & Poedts, Stefaan, ApJS, 247, 21
22. Electromagnetic Ion-Ion Instabilities in Space Plasmas: Effects of Suprathermal Populations [17]
    Shaaban, S. M., Lazar, M., López, R. A. & Poedts, S., ApJ, 899, 20
23. A new class of discontinuous solar wind solutions [5]
    Shergelashvili, Bidzina M., Melnik, Velentin N., Dididze, Grigol, Fichtner, Horst, Brenn, Günter, Poedts, Stefaan, Foysi, Holger, Khodachenko, Maxim L. & Zaqarashvili, Teimuraz V., MNRAS, 496, 1023
24. Numerical simulations of shear-induced consecutive coronal mass ejections [13]
    Talpeanu, D.-C., Chané, E., Poedts, S., D'Huys, E., Mierla, M., Roussev, I. & Hosteaux, S., A&A, 637, A77
25. Fire-hose instability of inhomogeneous plasma flows with heat fluxes [6]
    Uchava, E. S., Tevzadze, A. G., Shergelashvili, B. M., Dzhalilov, N. S. & Poedts, S., Physics of Plasmas, 27, 112901
26. The effect of drifts on the decay phase of SEP events [24]
    Wijsen, N., Aran, A., Sanahuja, B., Pomoell, J. & Poedts, S., A&A, 634, A82

2019

1. The Magnetic Morphology of Magnetic Clouds: Multi-spacecraft Investigation of Twisted and Writhed Coronal Mass Ejections [28]
   Al-Haddad, N., Poedts, S., Roussev, I., Farrugia, C. J., Yu, W. & Lugaz, N., ApJ, 870, 100
2. Evolution of Coronal Mass Ejection Properties in the Inner Heliosphere: Prediction for the Solar Orbiter and Parker Solar Probe [13]
   Al-Haddad, Nada, Lugaz, Noé, Poedts, Stefaan, Farrugia, Charles J., Nieves-Chinchilla, Teresa & Roussev, Ilia I., ApJ, 884, 179
3. A GPU-enabled implicit Finite Volume solver for the ideal two-fluid plasma model on unstructured grids [6]
   Alonso Asensio, Isaac, Alvarez Laguna, Alejandro, Aissa, Mohamed Hassanine, Poedts, Stefaan, Ozak, Nataly & Lani, Andrea, Computer Physics Communications, 239, 16
4. Reconstructing Coronal Hole Areas With EUHFORIA and Adapted WSA Model: Optimizing the Model Parameters [45]
   Asvestari, E., Heinemann, S. G., Temmer, M., Pomoell, J., Kilpua, E., Magdalenic, J. & Poedts, S., Journal of Geophysical Research (Space Physics), 124, 8280
5. Comparative analysis of solar radio bursts before and during CME propagation [3]
   Dididze, G., Shergelashvili, B. M., Melnik, V. N., Dorovskyy, V. V., Brazhenko, A. I., Poedts, S., Zaqarashvili, T. V. & Khodachenko, M., A&A, 625, A63
6. Magnetohydrodynamics of Laboratory and Astrophysical Plasmas [92]
   Goedbloed, Hans, Keppens, Rony & Poedts, Stefaan,
7. Assessing the Performance of EUHFORIA Modeling the Background Solar Wind [49]
   Hinterreiter, Jürgen, Magdalenic, Jasmina, Temmer, Manuela, Verbeke, Christine, Jebaraj, Immanuel Christopher, Samara, Evangelia, Asvestari, Eleanna, Poedts, Stefaan, Pomoell, Jens, Kilpua, Emilia, Rodriguez, Luciano, Scolini, Camilla & Isavnin, Alexey, Solar Physics, 294, 170
8. Effect of the solar wind density on the evolution of normal and inverse coronal mass ejections [18]
   Hosteaux, S., Chané, E. & Poedts, S., A&A, 632, A89
9. Multipoint Observations of the June 2012 Interacting Interplanetary Flux Ropes [40]
   Kilpua, Emilia K. J., Good, Simon W., Palmerio, Erika, Asvestari, Eleanna, Lumme, Erkka, Ala-Lahti, Matti, Kalliokoski, Milla M. H., Morosan, Diana E., Pomoell, Jens, Price, Daniel J., Magdalenić, Jasmina, Poedts, Stefaan & Futaana, Yoshifumi, Frontiers in Astronomy and Space Sciences, 6, 50
10. Whistler instability stimulated by the suprathermal electrons present in space plasmas [28]
    Lazar, M., López, R. A., Shaaban, S. M., Poedts, S. & Fichtner, H., Astrophysics and Space Science, 364, 171
11. Particle-in-cell Simulations of the Whistler Heat-flux Instability in Solar Wind Conditions [27]
    López, R. A., Shaaban, S. M., Lazar, M., Poedts, S., Yoon, P. H., Micera, A. & Lapenta, G., ApJ, 882, L8
12. Particle-in-cell Simulations of Firehose Instability Driven by Bi-Kappa Electrons [41]
    López, R. A., Lazar, M., Shaaban, S. M., Poedts, S., Yoon, P. H., Viñas, A. F. & Moya, P. S., ApJ, 873, L20
13. Slurm: Fluid particle-in-cell code for plasma modeling [5]
    Olshevsky, V., Bacchini, F., Poedts, S. & Lapenta, G., Computer Physics Communications, 235, 16
14. Multipoint Study of Successive Coronal Mass Ejections Driving Moderate Disturbances at 1 au [30]
    Palmerio, Erika, Scolini, Camilla, Barnes, David, Magdalenić, Jasmina, West, Matthew J., Zhukov, Andrei N., Rodriguez, Luciano, Mierla, Marilena, Good, Simon W., Morosan, Diana E., Kilpua, Emilia K. J., Pomoell, Jens & Poedts, Stefaan, ApJ, 878, 37
15. Forecasting space weather with EUHFORIA in the virtual space weather modeling centre [6]
    Poedts, S., Plasma Physics and Controlled Fusion, 61, 014011
16. Plasma heating by magnetoacoustic wave propagation in the vicinity of a 2.5D magnetic null-point [12]
    Sabri, S., Poedts, S. & Ebadi, H., A&A, 623, A81
17. Observation-based modelling of magnetised coronal mass ejections with EUHFORIA [106]
    Scolini, C., Rodriguez, L., Mierla, M., Pomoell, J. & Poedts, S., A&A, 626, A122
18. The Interplay of the Solar Wind Core and Suprathermal Electrons: A Quasilinear Approach for Firehose Instability [23]
    Shaaban, S. M., Lazar, M., Yoon, P. H. & Poedts, S., ApJ, 871, 237
19. Firehose instabilities triggered by the solar wind suprathermal electrons [40]
    Shaaban, S. M., Lazar, M., López, R. A., Fichtner, H. & Poedts, S., MNRAS, 483, 5642
20. Quasi-linear approach of the whistler heat-flux instability in the solar wind [31]
    Shaaban, S. M., Lazar, M., Yoon, P. H., Poedts, S. & López, R. A., MNRAS, 486, 4498
21. Quasilinear approach of the cumulative whistler instability in fast solar wind: Constraints of electron temperature anisotropy [19]
    Shaaban, S. M., Lazar, M., Yoon, P. H. & Poedts, S., A&A, 627, A76
22. On Polarization of Solar Decameter Spikes [0]
    Shevchuk, M., Melnik, V., Dorovskyy, V., Brazhenko, A., Frantsuzenko, A., Konovalenko, A., Poedts, S. & Magdalenic, J., Eleventh Workshop on Solar Influences on the Magnetosphere, Ionosphere and Atmosphere (Editors: Georgieva, Katya, Kirov, Boian & Danov, Dimitar), p. 40
23. The evolution of coronal mass ejections in the inner heliosphere: Implementing the spheromak model with EUHFORIA [97]
    Verbeke, C., Pomoell, J. & Poedts, S., A&A, 627, A111
24. A Case for Electron-Astrophysics [6]
    Verscharen, Daniel, Wicks, Robert T., Alexandrova, Olga, Bruno, Roberto, Burgess, David, Chen, Christopher H. K., D'Amicis, Raffaella, De Keyser, Johan, Dudok de Wit, Thierry, Franci, Luca, He, Jiansen, Henri, Pierre, Kasahara, Satoshi, Khotyaintsev, Yuri, Klein, Kristopher G., Lavraud, Benoit, Maruca, Bennett A., Maksimovic, Milan, Plaschke, Ferdinand, Poedts, Stefaan, Reynolds, Chirstopher S., Roberts, Owen, Sahraoui, Fouad, Saito, Shinji, Salem, Chadi S., Saur, Joachim, Servidio, Sergio, Stawarz, Julia E., Stverak, Stepan & Told, Daniel, arXiv:1908.02206
25. Spreading protons in the heliosphere: a note on cross-field diffusion effects [5]
    Wijsen, N., Aran, A., Pomoell, J. & Poedts, S., Journal of Physics Conference Series, Journal of Physics Conference Series, 1332, p. 012018
26. Interplanetary spread of solar energetic protons near a high-speed solar wind stream [21]
    Wijsen, N., Aran, A., Pomoell, J. & Poedts, S., A&A, 624, A47
27. Modelling three-dimensional transport of solar energetic protons in a corotating interaction region generated with EUHFORIA [59]
    Wijsen, N., Aran, A., Pomoell, J. & Poedts, S., A&A, 622, A28

2018

1. Fully-implicit finite volume method for the ideal two-fluid plasma model [15]
   Alvarez Laguna, A., Ozak, N., Lani, A., Deconinck, H. & Poedts, S., Computer Physics Communications, 231, 31
2. A Versatile Numerical Method for the Multi-Fluid Plasma Model in Partially- and Fully-Ionized Plasmas [2]
   Alvarez-Laguna, A., Ozak, N., Lani, A., Mansour, N. N., Deconinck, H. & Poedts, S., Journal of Physics Conference Series, Journal of Physics Conference Series, 1031, p. 012015
3. Quasi-electrostatic twisted waves in Lorentzian dusty plasmas [6]
   Arshad, Kashif, Lazar, M. & Poedts, S., Planetary and Space Science, 156, 139
4. Evidence for Precursors of the Coronal Hole Jets in Solar Bright Points [11]
   Bagashvili, Salome R., Shergelashvili, Bidzina M., Japaridze, Darejan R., Kukhianidze, Vasil, Poedts, Stefaan, Zaqarashvili, Teimuraz V., Khodachenko, Maxim L. & De Causmaecker, Patrick, ApJ, 855, L21
5. Ultrahigh-resolution model of a breakout CME embedded in the solar wind [25]
   Hosteaux, S., Chané, E., Decraemer, B., Talpeanu, D.-C. & Poedts, S., A&A, 620, A57
6. MHD Kelvin-Helmholtz instability in the anisotropic solar wind plasma [12]
   Ismayilli, R. F., Dzhalilov, N. S., Shergelashvili, B. M., Poedts, S. & Pirguliyev, M. Sh., Physics of Plasmas, 25, 062903
7. On the Evolution of Pre-Flare Patterns of a 3-Dimensional Model of AR 11429 [2]
   Korsós, M. B., Poedts, S., Gyenge, N., Georgoulis, M. K., Yu, S., Bisoi, S. K., Yan, Y., Ruderman, M. S. & Erdélyi, R., Space Weather of the Heliosphere: Processes and Forecasts (Editors: Foullon, Claire & Malandraki, Olga E.), IAU Symposium, 335, p. 294
8. Temperature anisotropy instabilities stimulated by the interplay of the core and halo electrons in space plasmas [27]
   Lazar, M., Shaaban, S. M., Fichtner, H. & Poedts, S., Physics of Plasmas, 25, 022902
9. On the effects of suprathermal populations in dusty plasmas: The case of dust-ion-acoustic waves [22]
   Lazar, M., Kourakis, I., Poedts, S. & Fichtner, H., Planetary and Space Science, 156, 130
10. Suprathermal Spontaneous Emissions in κ-distributed Plasmas [14]
    Lazar, M., Kim, S., López, R. A., Yoon, P. H., Schlickeiser, R. & Poedts, S., ApJ, 868, L25
11. Generation and evolution of anisotropic turbulence and related energy transfer in drifting proton-alpha plasmas [6]
    Maneva, Y. G. & Poedts, S., A&A, 613, A10
12. Interferometric Observations of the Quiet Sun at 20 and 25 MHz in May 2014 [6]
    Melnik, V. N., Shepelev, V. A., Poedts, S., Dorovskyy, V. V., Brazhenko, A. I. & Rucker, H. O., Solar Physics, 293, 97
13. Association between Tornadoes and Instability of Hosting Prominences [6]
    Mghebrishvili, Irakli, Zaqarashvili, Teimuraz V., Kukhianidze, Vasil, Kuridze, David, Tsiklauri, David, Shergelashvili, Bidzina M. & Poedts, Stefaan, ApJ, 861, 112
14. Association between Tornadoes and Instability of Hosting Prominences [0]
    Mghebrishvili, Irakli, Zaqarashvili, Teimuraz, Kukhianidze, Vasil, Kuridze, David, Tsiklauri, David, Shergelashvili, Bidzina & Poedts, Stefaan, Catalyzing Solar Connections, p. 20
15. EUHFORIA: European heliospheric forecasting information asset [378]
    Pomoell, Jens & Poedts, S., Journal of Space Weather and Space Climate, 8, A35
16. Effect of the Initial Shape of Coronal Mass Ejections on 3-D MHD Simulations and Geoeffectiveness Predictions [58]
    Scolini, C., Verbeke, C., Poedts, S., Chané, E., Pomoell, J. & Zuccarello, F. P., Space Weather, 16, 754
17. Halo Coronal Mass Ejections during Solar Cycle 24: reconstruction of the global scenario and geoeffectiveness [38]
    Scolini, Camilla, Messerotti, Mauro, Poedts, Stefaan & Rodriguez, Luciano, Journal of Space Weather and Space Climate, 8, A9
18. Stimulated Mirror Instability From the Interplay of Anisotropic Protons and Electrons, and their Suprathermal Populations [20]
    Shaaban, S. M., Lazar, M., Astfalk, P. & Poedts, S., Journal of Geophysical Research (Space Physics), 123, 1754
19. Clarifying the solar wind heat flux instabilities [55]
    Shaaban, S. M., Lazar, M. & Poedts, S., MNRAS, 480, 310
20. Beaming electromagnetic (or heat-flux) instabilities from the interplay with the electron temperature anisotropies [37]
    Shaaban, S. M., Lazar, M., Yoon, P. H. & Poedts, S., Physics of Plasmas, 25, 082105
21. On the Observational Properties of the Decameter Striae [0]
    Shevchuk, M. V., Melnik, V. N., Poedts, S., Dorovskyy, V. V., Magdalenic, J. & Konovalenko, A. A., 2018 2nd URSI Atlantic Radio Science Meeting (AT-RASC), 2, p. 258
22. Initiation of Stealth CMEs: Clues from Numerical Modelling and In-Situ Comparisons [0]
    Talpeanu, Dana-Camelia, Zuccarello, Francesco P., Chan\xC3, Emmanuel, Poedts, Stefaan, D'Huys, Elke, Hosteaux, Skralan & Mierla, Marilena, Catalyzing Solar Connections, p. 14

2017

1. Effect of Radiation on Chromospheric Magnetic Reconnection: Reactive and Collisional Multi-fluid Simulations [29]
   Alvarez Laguna, A., Lani, A., Mansour, N. N., Deconinck, H. & Poedts, S., ApJ, 842, 117
2. Ion acoustic wave damping in a non-Maxwellian bi-ion electron plasma in the presence of dust [9]
   Arshad, Kashif, Maneva, Yana G. & Poedts, S., Physics of Plasmas, 24, 093708
3. Kinetic study of electrostatic twisted waves instability in nonthermal dusty plasmas [23]
   Arshad, Kashif, Lazar, M., Mahmood, Shahzad & Aman-ur-Rehman, Poedts, S., Physics of Plasmas, 24, 033701
4. A new Particle-in-Cell method for modeling magnetized fluids [5]
   Bacchini, Fabio, Olshevsky, Vyacheslav, Poedts, Stefaan & Lapenta, Giovanni, Computer Physics Communications, 210, 79
5. Statistical properties of coronal hole rotation rates: Are they linked to the solar interior? [29]
   Bagashvili, S. R., Shergelashvili, B. M., Japaridze, D. R., Chargeishvili, B. B., Kosovichev, A. G., Kukhianidze, V., Ramishvili, G., Zaqarashvili, T. V., Poedts, S., Khodachenko, M. L. & De Causmaecker, P., A&A, 603, A134
6. How is the Jovian main auroral emission affected by the solar wind? [37]
   Chané, E., Saur, J., Keppens, R. & Poedts, S., Journal of Geophysical Research (Space Physics), 122, 1960
7. The Magnetosphere of the Earth under Sub-Alfvénic Solar Wind Conditions as Observed on 24 and 25 May 2002 [2]
   Chané, Emmanuel, Saur, Joachim, Raeder, Joachim, Neubauer, Fritz M., Maynard, Kristofor M. & Poedts, Stefaan, Dawn-Dusk Asymmetries in Planetary Plasma Environments (Editors: Haaland, Stein, Runov, Andrei & Forsyth, Colin), 230, p. 1
8. Solar signatures and eruption mechanism of the August 14, 2010 coronal mass ejection (CME) [15]
   D'Huys, Elke, Seaton, Daniel B., De Groof, Anik, Berghmans, David & Poedts, Stefaan, Journal of Space Weather and Space Climate, 7, A7
9. Properties of groups of solar S-bursts in the decameter band [0]
   Dorovskyy, V. V., Melnik, V. N., Konovalenko, A. A., Brazhenko, A., Poedts, S., Rucker, H. O. & Panchenko, M., Planetary Radio Emissions VIII (Editors: Fischer, G., Mann, G., Panchenko, M. & Zarka, P.), p. 369
10. Long-period oscillations of active region patterns: least-squares mapping on second-order curves [8]
    Dumbadze, G., Shergelashvili, B. M., Kukhianidze, V., Ramishvili, G., Zaqarashvili, T. V., Khodachenko, M., Gurgenashvili, E., Poedts, S. & De Causmaecker, P., A&A, 597, A93
11. Firehose constraints of the bi-Kappa-distributed electrons: a zero-order approach for the suprathermal electrons in the solar wind [41]
    Lazar, M., Shaaban, S. M., Poedts, S. & Štverák, Š., MNRAS, 464, 564
12. Instability constraints for the electron temperature anisotropy in the slow solar wind. Thermal core vs. suprathermal halo [1]
    Lazar, M., Shaaban, S. M., Pierrard, V., Fichtner, H. & Poedts, S., arXiv:1704.05311
13. Dual Maxwellian-Kappa modeling of the solar wind electrons: new clues on the temperature of Kappa populations [72]
    Lazar, M., Pierrard, V., Shaaban, S. M., Fichtner, H. & Poedts, S., A&A, 602, A44
14. Multi-fluid Modeling of Magnetosonic Wave Propagation in the Solar Chromosphere: Effects of Impact Ionization and Radiative Recombination [51]
    Maneva, Yana G., Alvarez Laguna, Alejandro, Lani, Andrea & Poedts, Stefaan, ApJ, 836, 197
15. Quasi-oscillatory dynamics observed in ascending phase of the flare on March 6, 2012 [2]
    Philishvili, E., Shergelashvili, B. M., Zaqarashvili, T. V., Kukhianidze, V., Ramishvili, G., Khodachenko, M., Poedts, S. & De Causmaecker, P., A&A, 600, A67
16. Shaping the solar wind temperature anisotropy by the interplay of electron and proton instabilities [31]
    Shaaban, S. M., Lazar, M., Poedts, S. & Elhanbaly, A., Astrophysics and Space Science, 362, 13
17. The decameter spikes as a tool for the coronal plasma parameters determination [0]
    Shevchuk, M. V., Melnik, V. N., Poedts, S., Dorovskyy, V. V., Magdalenic, J., Konovalenko, A. A., Brazhenko, A. I., Briand, C., Frantsuzenko, A. V., Rucker, H. O. & Zarka, P., 2017 XXXIInd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS), p. 315

2016

1. A fully-implicit finite-volume method for multi-fluid reactive and collisional magnetized plasmas on unstructured meshes [35]
   Alvarez Laguna, A., Lani, A., Deconinck, H., Mansour, N. N. & Poedts, S., Journal of Computational Physics, 318, 252
2. The Effect of Limited Sample Sizes on the Accuracy of the Estimated Scaling Parameter for Power-Law-Distributed Solar Data [19]
   D'Huys, Elke, Berghmans, David, Seaton, Daniel B. & Poedts, Stefaan, Solar Physics, 291, 1561
3. Rieger-type Periodicity during Solar Cycles 14-24: Estimation of Dynamo Magnetic Field Strength in the Solar Interior [68]
   Gurgenashvili, Eka, Zaqarashvili, Teimuraz V., Kukhianidze, Vasil, Oliver, Ramon, Ballester, Jose Luis, Ramishvili, Giorgi, Shergelashvili, Bidzina, Hanslmeier, Arnold & Poedts, Stefaan, ApJ, 826, 55
4. Shear Instability Analysis of MHD Discontinuities in the Solar Wind Conditions [2]
   Ismayilli, R. F., Dzhalilov, N. S., Shergelashvili, B. M., Poedts, S. & Pirguliyev, M. Sh., Azerbaijani Astronomical Journal, 11, 23
5. Kelvin-Helmholtz Instability in the Solar Wind Plasmas: 16-Momentum Fluid Formalism [0]
   Ismayilli, R. F., Dzhalilov, N. S., Shergelashvili, B. M., Poedts, S. & Pirguliyev, M. Sh., Azerbaijani Astronomical Journal, 11, 15
6. A small mission concept to the Sun-Earth Lagrangian L5 point for innovative solar, heliospheric and space weather science [31]
   Lavraud, B., Liu, Y., Segura, K., He, J., Qin, G., Temmer, M., Vial, J.-C., Xiong, M., Davies, J. A., Rouillard, A. P., Pinto, R., Auchère, F., Harrison, R. A., Eyles, C., Gan, W., Lamy, P., Xia, L., Eastwood, J. P., Kong, L., Wang, J., Wimmer-Schweingruber, R. F., Zhang, S., Zong, Q., Soucek, J., An, J., Prech, L., Zhang, A., Rochus, P., Bothmer, V., Janvier, M., Maksimovic, M., Escoubet, C. P., Kilpua, E. K. J., Tappin, J., Vainio, R., Poedts, S., Dunlop, M. W., Savani, N., Gopalswamy, N., Bale, S. D., Li, G., Howard, T., DeForest, C., Webb, D., Lugaz, N., Fuselier, S. A., Dalmasse, K., Tallineau, J., Vranken, D. & Fernández, J. G., Journal of Atmospheric and Solar-Terrestrial Physics, 146, 171
7. Firehose constraints for the solar wind suprathermal electrons [0]
   Lazar, M., Shaaban, S. M., Poedts, S. & Štverák, Š., arXiv:1604.05628
8. Mixing the Solar Wind Proton and Electron Scales: Effects of Electron Temperature Anisotropy on the Oblique Proton Firehose Instability [19]
   Maneva, Y., Lazar, M., Viñas, A. & Poedts, S., ApJ, 832, 64
9. Evolution of relative drifts and temperature anisotropies in expanding collisionless plasmas—1.5D vs. 2.5D hybrid simulations [2]
   Maneva, Y. G., Poedts, S. & Araneda, J. A., Space Plasma Physics, American Institute of Physics Conference Series, 1714, p. 030004
10. Preferential heating of oxygen 5⁺ ions by finite-amplitude oblique Alfvén waves [2]
    Maneva, Yana G., Viñas, Adolfo, Araneda, Jaime & Poedts, Stefaan, Solar Wind 14, American Institute of Physics Conference Series, 1720, p. 040011
11. The Electron Temperature and Anisotropy in the Solar Wind. Comparison of the Core and Halo Populations [102]
    Pierrard, V., Lazar, M., Poedts, S., Štverák, Š., Maksimovic, M. & Trávníček, P. M., Solar Physics, 291, 2165
12. Self-consistent evolution models for slow CMEs up to 1 AU [5]
    Poedts, S., Pomoell, J. & Zuccarello, F. P., Space Plasma Physics, American Institute of Physics Conference Series, 1714, p. 030002
13. Effects of suprathermal electrons on the proton temperature anisotropy in space plasmas: Electromagnetic ion-cyclotron instability [17]
    Shaaban, S. M., Lazar, M., Poedts, S. & Elhanbaly, A., Astrophysics and Space Science, 361, 193
14. The interplay of the solar wind proton core and halo populations: EMIC instability [29]
    Shaaban, S. M., Lazar, M., Poedts, S. & Elhanbaly, A., Journal of Geophysical Research (Space Physics), 121, 6031
15. The Storm of Decameter Spikes During the Event of 14 June 2012 [16]
    Shevchuk, N. V., Melnik, V. N., Poedts, S., Dorovskyy, V. V., Magdalenic, J., Konovalenko, A. A., Brazhenko, A. I., Briand, C., Frantsuzenko, A. V., Rucker, H. O. & Zarka, P., Solar Physics, 291, 211

2015

1. Simulations of the Earth's magnetosphere embedded in sub-Alfvénic solar wind on 24 and 25 May 2002 [22]
   Chané, E., Raeder, J., Saur, J., Neubauer, F. M., Maynard, K. M. & Poedts, S., Journal of Geophysical Research (Space Physics), 120, 8517
2. SEPEM: A tool for statistical modeling the solar energetic particle environment [54]
   Crosby, Norma, Heynderickx, Daniel, Jiggens, Piers, Aran, Angels, Sanahuja, Blai, Truscott, Pete, Lei, Fan, Jacobs, Carla, Poedts, Stefaan, Gabriel, Stephen, Sandberg, Ingmar, Glover, Alexi & Hilgers, Alain, Space Weather, 13, 406
3. Decameter U-burst Harmonic Pair from a High Loop [13]
   Dorovskyy, V. V., Melnik, V. N., Konovalenko, A. A., Bubnov, I. N., Gridin, A. A., Shevchuk, N. V., Rucker, H. O., Poedts, S. & Panchenko, M., Solar Physics, 290, 181
4. Fine and Superfine Structure of the Decameter-Hectometer Type II Burst on 7 June 2011 [16]
   Dorovskyy, V. V., Melnik, V. N., Konovalenko, A. A., Brazhenko, A. I., Panchenko, M., Poedts, S. & Mykhaylov, V. A., Solar Physics, 290, 2031
5. Constraints for the aperiodic O-mode streaming instability [4]
   Lazar, M., Schlickeiser, R., Poedts, S., Stockem, A. & Vafin, S., Physics of Plasmas, 22, 012102
6. Destabilizing effects of the suprathermal populations in the solar wind [98]
   Lazar, M., Poedts, S. & Fichtner, H., A&A, 582, A124
7. Towards realistic parametrization of the kinetic anisotropy and the resulting instabilities in space plasmas. Electromagnetic electron-cyclotron instability in the solar wind [39]
   Lazar, M., Poedts, S., Schlickeiser, R. & Dumitrache, C., MNRAS, 446, 3022
8. Dissipation of Parallel and Oblique Alfvén-Cyclotron Waves—Implications for Heating of Alpha Particles in the Solar Wind [21]
   Maneva, Y. G., Viñas, Adolfo F., Moya, Pablo S., Wicks, Robert T. & Poedts, Stefaan, ApJ, 814, 33
9. Dynamics of a Solar Prominence Tornado Observed by SDO/AIA on 2012 November 7-8 [14]
   Mghebrishvili, Irakli, Zaqarashvili, Teimuraz V., Kukhianidze, Vasil, Ramishvili, Giorgi, Shergelashvili, Bidzina, Veronig, Astrid & Poedts, Stefaan, ApJ, 810, 89
10. Electrostatic ion perturbations in kinematically complex shear flows [4]
    Osmanov, Z., Rogava, A. & Poedts, S., New Journal of Physics, 17, 043019
11. Numerical Simulations of a Flux Rope Ejection [6]
    Pagano, P., Mackay, D. H. & Poedts, S., Journal of Astrophysics and Astronomy, 36, 123
12. Coronal Heating & Solar Wind Acceleration by Drift Waves [0]
    Poedts, S., Kanella, Ch & Lapenta, G., Journal of Physics Conference Series, Journal of Physics Conference Series, 642, p. 012021
13. Modelling large solar proton events with the shock-and-particle model. Extraction of the characteristics of the MHD shock front at the cobpoint [31]
    Pomoell, Jens, Aran, Angels, Jacobs, Carla, Rodríguez-Gasén, Rosa, Poedts, Stefaan & Sanahuja, Blai, Journal of Space Weather and Space Climate, 5, A12
14. Effects of Electrons on the Electromagnetic Ion Cyclotron Instability: Solar Wind Implications [28]
    Shaaban, S. M., Lazar, M., Poedts, S. & Elhanbaly, A., ApJ, 814, 34
15. Quasilinear saturation of the aperiodic ordinary mode streaming instability [13]
    Stockem Novo, A., Yoon, P. H., Lazar, M., Schlickeiser, R., Poedts, S. & Seough, J., Physics of Plasmas, 22, 092301
16. Formation and evolution of coronal rain observed by SDO/AIA on February 22, 2012 [29]
    Vashalomidze, Z., Kukhianidze, V., Zaqarashvili, T. V., Oliver, R., Shergelashvili, B., Ramishvili, G., Poedts, S. & De Causmaecker, P., A&A, 577, A136

2014

1. Observational Characteristics of Coronal Mass Ejections without Low-coronal Signatures [70]
   D'Huys, E., Seaton, D. B., Poedts, S. & Berghmans, D., ApJ, 795, 49
2. Electrostatic plasma instabilities driven by neutral gas flows in the solar chromosphere [11]
   Gogoberidze, G., Voitenko, Y., Poedts, S. & De Keyser, J., MNRAS, 438, 3568
3. A GPU-enabled Finite Volume solver for global magnetospheric simulations on unstructured grids [30]
   Lani, Andrea, Yalim, Mehmet Sarp & Poedts, Stefaan, Computer Physics Communications, 185, 2538
4. Solar Wind Electron Strahls Associated with a High-Latitude CME: Ulysses Observations [11]
   Lazar, M., Pomoell, J., Poedts, S., Dumitrache, C. & Popescu, N. A., Solar Physics, 289, 4239
5. The Electron Firehose and Ordinary-Mode Instabilities in Space Plasmas [30]
   Lazar, M., Poedts, S., Schlickeiser, R. & Ibscher, D., Solar Physics, 289, 369
6. Instability of the parallel electromagnetic modes in Kappa distributed plasmas - II. Electromagnetic ion-cyclotron modes [35]
   Lazar, M. & Poedts, S., MNRAS, 437, 641
7. The interplay of Kappa and core populations in the solar wind: Electromagnetic electron cyclotron instability [26]
   Lazar, M., Poedts, S. & Schlickeiser, R., Journal of Geophysical Research (Space Physics), 119, 9395
8. Solar Decameter Spikes [18]
   Melnik, V. N., Shevchuk, N. V., Konovalenko, A. A., Rucker, H. O., Dorovskyy, V. V., Poedts, S. & Lecacheux, A., Solar Physics, 289, 1701
9. Simulating AIA observations of a flux rope ejection [24]
   Pagano, P., Mackay, D. H. & Poedts, S., A&A, 568, A120
10. Magnetohydrodynamic study on the effect of the gravity stratification on flux rope ejections [0]
    Pagano, Paolo, Mackay, Duncan H. & Poedts, Stefaan, Nature of Prominences and their Role in Space Weather (Editors: Schmieder, Brigitte, Malherbe, Jean-Marie & Wu, S. T.), IAU Symposium, 300, p. 197
11. Variation of Proton Flux Profiles with the Observer's Latitude in Simulated Gradual SEP Events [16]
    Rodríguez-Gasén, R., Aran, A., Sanahuja, B., Jacobs, C. & Poedts, S., Solar Physics, 289, 1745
12. Overstability of acoustic waves in strongly magnetized anisotropic magnetohydrodynamic shear flows [3]
    Uchava, E. S., Shergelashvili, B. M., Tevzadze, A. G. & Poedts, S., Physics of Plasmas, 21, 082902
13. GRADSPMHD: A parallel MHD code based on the SPH formalism [6]
    Vanaverbeke, S., Keppens, R. & Poedts, S., Computer Physics Communications, 185, 1053
14. Features of coronal heating by drift waves [1]
    Vranjes, J. & Poedts, S., Journal of Physics Conference Series, Journal of Physics Conference Series, 511, p. 012054
15. Kinetic dust acoustic mode in inhomogeneous partially magnetized plasma [1]
    Vranjes, J. & Poedts, S., Journal of Physics Conference Series, Journal of Physics Conference Series, 511, p. 012011
16. Ion acoustic mode in permeating plasmas [2]
    Vranjes, J. & Poedts, S., Journal of Physics Conference Series, Journal of Physics Conference Series, 511, p. 012010
17. 3D Global Magnetohydrodynamic Simulations of the Solar Wind/Earth's Magnetosphere Interaction [1]
    Yalim, M. S. & Poedts, S., 8th International Conference of Numerical Modeling of Space Plasma Flows (ASTRONUM 2013) (Editors: Pogorelov, N. V., Audit, E. & Zank, G. P.), Astronomical Society of the Pacific Conference Series, 488, p. 192
18. Variations in EUV Irradiance: Comparison between LYRA, ESP, and SWAP Integrated Flux [1]
    Yalim, Mehmet Sarp & Poedts, Stefaan, Advances in Astronomy, 2014, 957461
19. Observational Evidence of Torus Instability as Trigger Mechanism for Coronal Mass Ejections: The 2011 August 4 Filament Eruption [70]
    Zuccarello, F. P., Seaton, D. B., Mierla, M., Poedts, S., Rachmeler, L. A., Romano, P. & Zuccarello, F., ApJ, 785, 88
20. Shearing motions and torus instability in the 2010 April 3 filament eruption [1]
    Zuccarello, F. P., Romano, P., Zuccarello, F. & Poedts, S., Nature of Prominences and their Role in Space Weather (Editors: Schmieder, Brigitte, Malherbe, Jean-Marie & Wu, S. T.), IAU Symposium, 300, p. 475

2013

1. Magnetic Field Configuration Models and Reconstruction Methods for Interplanetary Coronal Mass Ejections [84]
   Al-Haddad, N., Nieves-Chinchilla, T., Savani, N. P., Möstl, C., Marubashi, K., Hidalgo, M. A., Roussev, I. I., Poedts, S. & Farrugia, C. J., Solar Physics, 284, 129
2. SoFAST: Automated Flare Detection with the PROBA2/SWAP EUV Imager [12]
   Bonte, K., Berghmans, D., De Groof, A., Steed, K. & Poedts, S., Solar Physics, 286, 185
3. Modeling Jupiter's magnetosphere: Influence of the internal sources [52]
   Chané, E., Saur, J. & Poedts, S., Journal of Geophysical Research (Space Physics), 118, 2157
4. Forecasting the Earth's radiation belts and modelling solar energetic particle events: Recent results from SPACECAST [25]
   Horne, Richard B., Glauert, Sarah A., Meredith, Nigel P., Koskinen, Hannu, Vainio, Rami, Afanasiev, Alexandr, Ganushkina, Natalia Y., Amariutei, Olga A., Boscher, Daniel, Sicard, Angelica, Maget, Vincent, Poedts, Stefaan, Jacobs, Carla, Sanahuja, Blai, Aran, Angels, Heynderickx, Daniel & Pitchford, David, Journal of Space Weather and Space Climate, 3, A20
5. SWIFF: Space weather integrated forecasting framework [21]
   Lapenta, Giovanni, Pierrard, Viviane, Keppens, Rony, Markidis, Stefano, Poedts, Stefaan, Šebek, Ondřej, Trávníček, Pavel M., Henri, Pierre, Califano, Francesco, Pegoraro, Francesco, Faganello, Matteo, Olshevsky, Vyacheslav, Restante, Anna Lisa, Nordlund, Åke, Trier Frederiksen, Jacob, Mackay, Duncan H., Parnell, Clare E., Bemporad, Alessandro, Susino, Roberto & Borremans, Kris, Journal of Space Weather and Space Climate, 3, A05
6. Space Weather Prediction and Exascale Computing [5]
   Lapenta, Giovanni, Markidis, Stefano, Poedts, Stefaan & Vucinic, Dean, Computing in Science and Engineering, 15, 68
7. Electromagnetic electron whistler-cyclotron instability in bi-Kappa distributed plasmas [36]
   Lazar, M., Poedts, S. & Michno, M. J., A&A, 554, A64
8. Effect of gravitational stratification on the propagation of a CME [18]
   Pagano, P., Mackay, D. H. & Poedts, S., A&A, 560, A38
9. Magnetohydrodynamic simulations of the ejection of a magnetic flux rope [36]
   Pagano, P., Mackay, D. H. & Poedts, S., A&A, 554, A77
10. Numerical Simulations of Dome-Shaped EUV Waves from Different Active-Region Configurations [7]
    Selwa, M., Poedts, S. & DeVore, C. R., Solar Physics, 284, 515

2012

1. Study of Multiple Coronal Mass Ejections at Solar Minimum Conditions [26]
   Bemporad, A., Zuccarello, F. P., Jacobs, C., Mierla, M. & Poedts, S., Solar Physics, 281, 223
2. Observational evidence of Alfvén wings at the Earth [41]
   Chané, E., Saur, J., Neubauer, F. M., Raeder, J. & Poedts, S., Journal of Geophysical Research (Space Physics), 117, A09217
3. A Numerical Study of the Response of the Coronal Magnetic Field to Flux Emergence [12]
   Jacobs, C. & Poedts, S., Solar Physics, 280, 389
4. Modeling Space Plasma Dynamics with Anisotropic Kappa Distributions [30]
   Lazar, M., Pierrard, V., Poedts, S. & Schlickeiser, R., Multi-scale Dynamical Processes in Space and Astrophysical Plasmas (Editors: Leubner, Manfred P. & Vörös, Zoltán), Astrophysics and Space Science Proceedings, 33, p. 97
5. Suprathermal Particle Populations in the Solar Wind and Corona [10]
   Lazar, M., Schlickeiser, R. & Poedts, S., Exploring the Solar Wind (Editors: Lazar, Marian), p.241
6. Self-heating in kinematically complex magnetohydrodynamic flows [5]
   Osmanov, Zaza, Rogava, Andria & Poedts, Stefaan, Physics of Plasmas, 19, 012901
7. The birth of a solar eruption [0]
   Poedts, Stefaan, Nature Physics, 8, 783
8. Self-heating of Corona by Electrostatic Fields Driven by Sheared Flows [14]
   Saleem, H., Ali, S. & Poedts, S., ApJ, 748, 90
9. Dome-shaped EUV Waves from Rotating Active Regions [19]
   Selwa, M., Poedts, S. & DeVore, C. R., ApJ, 747, L21
10. Reply to the Comment by P. K. Shukla and M. Akbari-Moghanjoughi [5]
    Vranjes, J., Pandey, B. P. & Poedts, S., EPL (Europhysics Letters), 99, 65002
11. On quantum plasma: A plea for a common sense [17]
    Vranjes, J., Pandey, B. P. & Poedts, S., EPL (Europhysics Letters), 99, 25001
12. Numerical Modeling of the Initiation of Coronal Mass Ejections in Active Region NOAA 9415 [36]
    Zuccarello, F. P., Meliani, Z. & Poedts, S., ApJ, 758, 117
13. The Role of Streamers in the Deflection of Coronal Mass Ejections: Comparison between STEREO Three-dimensional Reconstructions and Numerical Simulations [110]
    Zuccarello, F. P., Bemporad, A., Jacobs, C., Mierla, M., Poedts, S. & Zuccarello, F., ApJ, 744, 66
14. The role of streamers in the deflection of coronal mass ejections [0]
    Zuccarello, F. P., Bemporad, A., Jacobs, C., Mierla, M., Poedts, S. & Zuccarello, F., Comparative Magnetic Minima: Characterizing Quiet Times in the Sun and Stars (Editors: Mandrini, Cristina H. & Webb, David F.), IAU Symposium, 286, p. 134
15. The role of photospheric shearing motions in a filament eruption related to the 2010 April 3 coronal mass ejection [9]
    Zuccarello, F. P., Romano, P., Zuccarello, F. & Poedts, S., A&A, 537, A28

2011

1. On the Internal Structure of the Magnetic Field in Magnetic Clouds and Interplanetary Coronal Mass Ejections: Writhe versus Twist [46]
   Al-Haddad, N., Roussev, I. I., Möstl, C., Jacobs, C., Lugaz, N., Poedts, S. & Farrugia, C. J., ApJ, 738, L18
2. Validation of CME Detection Software (CACTus) by Means of Simulated Data, and Analysis of Projection Effects on CME Velocity Measurements [8]
   Bonte, K., Jacobs, C., Robbrecht, E., De Groof, A., Berghmans, D. & Poedts, S., Solar Physics, 270, 253
3. Investigation of dynamics of self-similarly evolving magnetic clouds [6]
   Dalakishvili, G., Rogava, A., Lapenta, G. & Poedts, S., A&A, 526, A22
4. Magnetic clouds in the solar wind: a numerical assessment of analytical models [4]
   Dalakishvili, G., Kleimann, J., Fichtner, H. & Poedts, S., A&A, 536, A100
5. A modified orbital motion limited (OML) theory [0]
   Ehsan, Zahida, Tsintsadze, Nodar L. & Poedts, S., arXiv:1110.6304
6. Acceleration of dust particles by vortex ring [3]
   Ehsan, Zahida, Tsintsadze, N. L., Vranjes, J., Khan, R. & Poedts, S., Journal of Plasma Physics, 77, 155
7. Existence of Dust Atoms & Modified OML Theory [3]
   Ehsan, Zahida, Tsintsadze, N. L. & Poedts, S., Dusty/complex Plasmas: Basic and Interdisciplinary Research: Sixth International Conference on the Physics of Dusty Plasmas (Editors: Nosenko, Vladimir Yu., Shukla, Padma K., Thoma, Markus H. & Thomas, Hubertus M.), American Institute of Physics Conference Series, 1397, p. 383
8. Models of Imbalanced MHD Turbulence [0]
   Gogoberidze, G., Poedts, S. & Akhalkatsi, M., 3rd School and Workshop on Space Plasma Physics (Editors: Zhelyazkov, Ivan & Mishonov, Todor), American Institute of Physics Conference Series, 1356, p. 75
9. Weak and Strong MHD Turbulence [0]
   Gogoberidze, G., Mahajan, S., Poedts, S. & Akhalkatsi, M., 3rd School and Workshop on Space Plasma Physics (Editors: Zhelyazkov, Ivan & Mishonov, Todor), American Institute of Physics Conference Series, 1356, p. 67
10. Electron streams formation and secondary two stream instability onset in the post-saturation regime of the classical Weibel instability [12]
    Innocenti, M. E., Lazar, M., Markidis, S., Lapenta, G. & Poedts, S., Physics of Plasmas, 18, 052104
11. A polytropic model for the solar wind [33]
    Jacobs, C. & Poedts, S., Advances in Space Research, 48, 1958
12. Models for coronal mass ejections [19]
    Jacobs, Carla & Poedts, Stefaan, Journal of Atmospheric and Solar-Terrestrial Physics, 73, 1148
13. Proton firehose instability in bi-Kappa distributed plasmas [47]
    Lazar, M., Poedts, S. & Schlickeiser, R., A&A, 534, A116
14. Instability of the parallel electromagnetic modes in Kappa distributed plasmas - I. Electron whistler-cyclotron modes [56]
    Lazar, M., Poedts, S. & Schlickeiser, R., MNRAS, 410, 663
15. Why should the latitude of the observer be considered when modeling gradual proton events? An insight using the concept of cobpoint [16]
    Rodríguez-Gasén, R., Aran, A., Sanahuja, B., Jacobs, C. & Poedts, S., Advances in Space Research, 47, 2140
16. Shear flow-driven electrostatic instabilities in low density and low temperature pair-ion plasmas with and without electrons [5]
    Saleem, H., Batool, N. & Poedts, S., Physics of Plasmas, 18, 052108
17. Magnetic helicity balance during a filament eruption that occurred in active region NOAA 9682 [14]
    Zuccarello, F. P., Romano, P., Zuccarello, F. & Poedts, S., A&A, 530, A36

2010

1. Side Magnetic Reconnections Induced by Coronal Mass Ejections: Observations and Simulations [14]
   Bemporad, A., Soenen, A., Jacobs, C., Landini, F. & Poedts, S., ApJ, 718, 251
2. Advanced Magnetohydrodynamics [125]
   Goedbloed, J. P., Keppens, Rony & Poedts, Stefaan,
3. Nonresonant electromagnetic instabilities in space plasmas: interplay of Weibel and firehose instabilities [4]
   Lazar, M., Poedts, S. & Schlickeiser, R., Twelfth International Solar Wind Conference (Editors: Maksimovic, M., Issautier, K., Meyer-Vernet, N., Moncuquet, M. & Pantellini, F.), American Institute of Physics Conference Series, 1216, p. 280
4. Is the Weibel instability enhanced by the suprathermal populations or not? [20]
   Lazar, M., Schlickeiser, R. & Poedts, S., Physics of Plasmas, 17, 062112
5. Counterstreaming magnetized plasmas with kappa distributions - II. Perpendicular wave propagation [22]
   Lazar, M., Tautz, R. C., Schlickeiser, R. & Poedts, S., MNRAS, 401, 362
6. Resonant Weibel instability in counterstreaming plasmas with temperature anisotropies [10]
   Lazar, M., Dieckmann, M. E. & Poedts, S., Journal of Plasma Physics, 76, 49
7. Self-heating and its possible relationship to chromospheric heating in slowly rotating stars [3]
   Rogava, Andria, Osmanov, Zaza & Poedts, Stefaan, MNRAS, 404, 224
8. Modeling of Local Magnetic Field Enhancements within Solar Flux Ropes [6]
   Romashets, E., Vandas, M. & Poedts, S., Solar Physics, 261, 271
9. Consistent Self-Similar Magnetohydrodynamics Evolution of Coronal Transients [5]
   Shapakidze, David, Debosscher, Arnold, Rogava, Andria & Poedts, Stefaan, ApJ, 712, 565
10. Kinetic instability of the dust acoustic mode in inhomogeneous, partially magnetized plasma with both positively and negatively charged grains [6]
    Vranjes, J. & Poedts, S., Physical Review E, 82, 026411
11. Nonlinear three-wave interaction in pair plasmas [1]
    Vranjes, J. & Poedts, S., Physical Review E, 81, 067401
12. Drift waves in the corona: heating and acceleration of ions at frequencies far below the gyrofrequency [23]
    Vranjes, J. & Poedts, S., MNRAS, 408, 1835
13. Features of ion acoustic waves in collisional plasmas [19]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 17, 022104
14. The Problem of Coronal Heating [2]
    Vranjes, J. & Poedts, S., New Frontiers in Advanced Plasma Physics (Editors: Eliasson, Bengt & Shukla, Padma K.), American Institute of Physics Conference Series, 1306, p. 201
15. Kinetic Instability of Drift-Alfvén Waves in Solar Corona and Stochastic Heating [21]
    Vranjes, J. & Poedts, S., ApJ, 719, 1335

2009

1. Characteristics of magnetised plasma flow around stationary and expanding magnetic clouds [3]
   Dalakishvili, G., Poedts, S., Fichtner, H. & Romashets, E., A&A, 507, 611
2. Linking two consecutive nonmerging magnetic clouds with their solar sources [67]
   Dasso, S., Mandrini, C. H., Schmieder, B., Cremades, H., Cid, C., Cerrato, Y., Saiz, E., Démoulin, P., Zhukov, A. N., Rodriguez, L., Aran, A., Menvielle, M. & Poedts, S., Journal of Geophysical Research (Space Physics), 114, A02109
3. Acceleration of soliton by nonlinear Landau damping of dust-helical waves [8]
   Ehsan, Zahida, Tsintsadze, Nodar L., Vranjes, J. & Poedts, S., Physics of Plasmas, 16, 053702
4. Acceleration of dust particles by vortex ring [0]
   Ehsan, Zahida, Tsintsadze, N. L., Vranjes, J., Coppins, M., Khan, R., Poedts, S. & Allen, J. E., arXiv:0911.2108
5. Farley-Buneman Instability in the Solar Chromosphere [26]
   Gogoberidze, G., Voitenko, Y., Poedts, S. & Goossens, M., ApJ, 706, L12
6. Weak and strong regimes of incompressible magnetohydrodynamic turbulence [3]
   Gogoberidze, G., Mahajan, S. M. & Poedts, S., Physics of Plasmas, 16, 072304
7. A Quaternionic Approach to Treat the Ideally Stationary Magnetohydrodynamic Equations [0]
   Gürlebeck, K., Kraußhar, R. S. & Poedts, S., Numerical Analysis and Applied Mathematics: International Conference on Numerical Analysis and Applied Mathematics 2009: Volume 1 and Volume 2 (Editors: Simos, Theodore E., Psihoyios, George & Tsitouras, Ch.), American Institute of Physics Conference Series, 1, p. 789
8. The Internal Structure of Coronal Mass Ejections: Are all Regular Magnetic Clouds Flux Ropes? [56]
   Jacobs, C., Roussev, I. I., Lugaz, N. & Poedts, S., ApJ, 695, L171
9. Acoustic oscillations in the field-free, gravitationally stratified cavities under solar bipolar magnetic canopies [22]
   Kuridze, D., Zaqarashvili, T. V., Shergelashvili, B. M. & Poedts, S., A&A, 505, 763
10. On the existence of Weibel instability in a magnetized plasma. I. Parallel wave propagation [30]
    Lazar, M., Schlickeiser, R. & Poedts, S., Physics of Plasmas, 16, 012106
11. Limits for the Firehose Instability in Space Plasmas [30]
    Lazar, M. & Poedts, S., Solar Physics, 258, 119
12. Cosmological Effects of Weibel-Type Instabilities [90]
    Lazar, M., Schlickeiser, R., Wielebinski, R. & Poedts, S., ApJ, 693, 1133
13. Firehose instability in space plasmas with bi-kappa distributions [58]
    Lazaré, M. & Poedtsé, S., A&A, 494, 311
14. Magnetic Flux Emergence and Shearing Motions as Trigger Mechanisms for Coronal Mass Ejections [0]
    Poedts, S., Soenen, A., Zuccarello, F. P., Jacobs, C. & van der Holst, B., Space Plasma Physics: School of Space Plasma Physics (Editors: Zhelyazkov, Ivan), American Institute of Physics Conference Series, 1121, p. 99
15. Numerical simulations of the solar corona and Coronal Mass Ejections [1]
    Poedts, Stefaan, Jacobs, Carla, van der Holst, Bart, Chané, Emmanuel & Keppens, Rony, Earth, Planets and Space, 61, 599
16. Three frontside full halo coronal mass ejections with a nontypical geomagnetic response [22]
    Rodriguez, L., Zhukov, A. N., Cid, C., Cerrato, Y., Saiz, E., Cremades, H., Dasso, S., Menvielle, M., Aran, A., Mandrini, C., Poedts, S. & Schmieder, B., Space Weather, 7, S06003
17. Magnetic helicity and active filament configuration [6]
    Romano, P., Zuccarello, F., Poedts, S., Soenen, A. & Zuccarello, F. P., A&A, 506, 895
18. The role of lateral magnetic reconnection in solar eruptive events [2]
    Soenen, A., Bemporad, A., Jacobs, C. & Poedts, S., Annales Geophysicae, 27, 3941
19. Numerical simulations of homologous coronal mass ejections in the solar wind [20]
    Soenen, A., Zuccarello, F. P., Jacobs, C., Poedts, S., Keppens, R. & van der Holst, B., A&A, 501, 1123
20. GRADSPH: A parallel smoothed particle hydrodynamics code for self-gravitating astrophysical fluid dynamics [25]
    Vanaverbeke, S., Keppens, R., Poedts, S. & Boffin, H., Computer Physics Communications, 180, 1164
21. A New Approach to the Coronal Heating Problem [0]
    Vranjes, J. & Poedts, S., New Developments in Nonlinear Plasma Physics (Editors: Eliasson, Bengt & Shukla, Padma K.), American Institute of Physics Conference Series, 1188, p. 153
22. Comment on ``Alfvén Instability in a Compressible Flow'' [1]
    Vranjes, J. & Poedts, S., Physical Review Letters, 103, 019501
23. Kinetic instability of ion acoustic mode in permeating plasmas [0]
    Vranjes, J., Poedts, S. & Ehsan, Z., arXiv:0906.3603
24. Effects of friction on modes in collisional multicomponent plasmas [0]
    Vranjes, J., Poedts, S., Kono, M. & Tanaka, M. Y., Journal of Physics Conference Series, Journal of Physics Conference Series, 162, p. 012017
25. Electric fields in solar magnetic structures due to gradient-driven instabilities: heating and acceleration of particles [20]
    Vranjes, J. & Poedts, S., MNRAS, 400, 2147
26. A new paradigm for solar coronal heating [26]
    Vranjes, J. & Poedts, S., EPL (Europhysics Letters), 86, 39001
27. On the role of perpendicular electron collisions in drift and acoustic wave instabilities [8]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 16, 022101
28. Kinetic instability of ion acoustic mode in permeating plasmas [17]
    Vranjes, J., Poedts, S. & Ehsan, Zahida, Physics of Plasmas, 16, 074501
29. Solar nanoflares and other smaller energy release events as growing drift waves [8]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 16, 092902
30. Diamagnetic current does not produce an instability in the solar corona [4]
    Vranjes, J. & Poedts, S., A&A, 503, 591
31. The universally growing mode in the solar atmosphere: coronal heating by drift waves [37]
    Vranjes, J. & Poedts, S., MNRAS, 398, 918
32. Models of Solar Wind Structures and Their Interaction with the Earth's Space Environment [24]
    Watermann, J., Wintoft, P., Sanahuja, B., Saiz, E., Poedts, S., Palmroth, M., Milillo, A., Metallinou, F.-A., Jacobs, C., Ganushkina, N. Y., Daglis, I. A., Cid, C., Cerrato, Y., Balasis, G., Aylward, A. D. & Aran, A., Space Science Reviews, 147, 233
33. Modelling the initiation of coronal mass ejections: magnetic flux emergence versus shearing motions [40]
    Zuccarello, F. P., Jacobs, C., Soenen, A., Poedts, S., van der Holst, B. & Zuccarello, F., A&A, 507, 441

2008

1. On the combination of ACE data with numerical simulations to determine the initial characteristics of a CME [24]
   Chané, E., Poedts, S. & van der Holst, B., A&A, 492, L29
2. Numerical Modeling of the Initiation of Coronal Mass Ejections [0]
   Jacobs, C., Lugaz, N., Poedts, S. & Roussev, I., European Solar Physics Meeting (Editors: Peter, H.), European Solar Physics Meeting, 12, p. 3.56
3. Acoustic oscillations in a field-free cavity under solar small-scale bipolar magnetic canopy [26]
   Kuridze, D., Zaqarashvili, T. V., Shergelashvili, B. M. & Poedts, S., Annales Geophysicae, 26, 2983
4. Counterstreaming magnetized plasmas with kappa distributions - I. Parallel wave propagation [74]
   Lazar, M., Schlickeiser, R., Poedts, S. & Tautz, R. C., MNRAS, 390, 168
5. Radiative Relaxation of Space Plasma Anisotropies [0]
   Lazar, M., Poedts, S. & Schlickeiser, R., European Solar Physics Meeting (Editors: Peter, H.), European Solar Physics Meeting, 12, p. 3.71
6. Magnetic flux emergence and shearing motions as CME trigger mechanisms [1]
   Poedts, S., Soenen, A., Zuccarello, F. P., Jacobs, C. & van der Hoist, B., Exploring the Solar System and the Universe (Editors: Mioc, Vasile, Dumitrche, Cristiana & Popescu, Nedelia A.), American Institute of Physics Conference Series, 1043, p. 291
7. Magnetic clouds seen at different locations in the heliosphere [33]
   Rodriguez, L., Zhukov, A. N., Dasso, S., Mandrini, C. H., Cremades, H., Cid, C., Cerrato, Y., Saiz, E., Aran, A., Menvielle, M., Poedts, S. & Schmieder, B., Annales Geophysicae, 26, 213
8. Magnetic field disturbances in the sheath region of a super-sonic interplanetary magnetic cloud [4]
   Romashets, E., Vandas, M. & Poedts, S., Annales Geophysicae, 26, 3153
9. Modeling of the magnetic field in the magnetosheath region [15]
   Romashets, E. P., Poedts, S. & Vandas, M., Journal of Geophysical Research (Space Physics), 113, A02203
10. Parametric Study of Breakout Coronal Mass Ejections in the Solar Wind [0]
    Soenen, A., Poedts, S. & van der Holst, B., European Solar Physics Meeting (Editors: Peter, H.), European Solar Physics Meeting, 12, p. 3.57
11. Drift Mode Driven by Shear Plasma Flow in Solar Atmosphere [0]
    Vranjes, J., Poedts, S. & Saleem, H., European Solar Physics Meeting (Editors: Peter, H.), European Solar Physics Meeting, 12, p. 3.21
12. Flux of Alfven Waves in the Solar Photosphere [0]
    Vranjes, J., Poedts, S., Pandey, B. P. & de Pontieu, B. P., European Solar Physics Meeting (Editors: Peter, H.), European Solar Physics Meeting, 12, p. 3.10
13. Global Modes in Spatially Limited Plasmas [0]
    Vranjes, J. & Poedts, S., Frontiers in Modern Plasma Physics: 2008 ICTP International Workshop on the Frontiers of Modern Plasma Physics (Editors: Shukla, Padma K., Eliasson, Bengt & Stenflo, Lennart), American Institute of Physics Conference Series, 1061, p. 168
14. Energy flux of Alfvén waves in weakly ionized plasma [69]
    Vranjes, J., Poedts, S., Pandey, B. P. & de Pontieu, B., A&A, 478, 553
15. Properties of Drift and ALFVÉN Waves in Collisional Plasmas [0]
    Vranjes, J., Poedts, S. & Pandey, B. P., New Aspects of Plasma Physics (Editors: Schukla, Padma K., Stenflo, Lennart & Eliasson, Bengt), p. 256
16. Comment on "Drift instabilities in the solar corona within the multi-fluid description" [Astron. Astrophys. {\bf 481}, 853 (2008)] [0]
    Vranjes, J. & Poedts, S., arXiv:0811.2326
17. Ion thermal effects in oscillating multi-ion plasma sheath theory [7]
    Vranjes, J., Pandey, B. P., Tanaka, M. Y. & Poedts, S., Physics of Plasmas, 15, 123505
18. Collisional energy transfer in two-component plasmas [13]
    Vranjes, J., Kono, M., Poedts, S. & Tanaka, M. Y., Physics of Plasmas, 15, 092107
19. Electrostatic modes in multi-ion and pair-ion collisional plasmas [70]
    Vranjes, J., Petrovic, D., Pandey, B. P. & Poedts, S., Physics of Plasmas, 15, 072104
20. Global convective cell formation in pair-ion plasmas [11]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 15, 044501
21. Note on the role of friction-induced momentum conservation in the collisional drift wave instability [8]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 15, 034504
22. Coupled gas acoustic and ion acoustic waves in weakly ionized plasma [2]
    Vranjes, J., Pandey, B. P. & Poedts, S., Publications de l'Observatoire Astronomique de Beograd, 84, 507
23. Magnetic field generation at ion acoustic time scale [0]
    Vranjes, J., Saleem, H. & Poedts, S., Publications de l'Observatoire Astronomique de Beograd, 84, 503
24. Growing drift-cyclotron modes in the hot solar atmosphere [14]
    Vranjes, J. & Poedts, S., A&A, 482, 653
25. Current Driven Acoustic Perturbations in Partially Ionized Collisional Plasmas [0]
    Vranjes, J., Poedts, S., Tanaka, M. Y. & Pandey, B. P., New Aspects of Plasma Physics (Editors: Schukla, Padma K., Stenflo, Lennart & Eliasson, Bengt), p. 285
26. Electrostatic waves in inhomogeneous pair-ion plasma [0]
    Vranjes, J., Pandey, B. P. & Poedts, S., Multifacets of Dusty Plasmas: Fifth International Conference on the Physics of Dusty Plasmas (Editors: Tito, José & Shukla, Padma K.), American Institute of Physics Conference Series, 1041, p. 339
27. Initiation of Coronal Mass Ejections by Magnetic Flux Emergence in the Framework of the Breakout Model [27]
    Zuccarello, F. P., Soenen, A., Poedts, S., Zuccarello, F. & Jacobs, C., ApJ, 689, L157
28. Modelling the Initiation of Coronal Mass Ejections by Magnetic Flux Emergence [0]
    Zuccarello, F. P., Soenen, A. & Poedts, S., European Solar Physics Meeting (Editors: Peter, H.), European Solar Physics Meeting, 12, p. 3.55

2007

1. Stabilizing effects of positron dynamics on the local and global drift modes [3]
   Ahmad, Ali, Saleem, H., Vranjes, J. & Poedts, S., Physics Letters A, 366, 466
2. MHD seismology of coronal loops using the period and damping of quasi-mode kink oscillations [127]
   Arregui, I., Andries, J., Van Doorsselaere, T., Goossens, M. & Poedts, S., A&A, 463, 333
3. The jovian magnetosphere: numerical simulations. [0]
   Chané, E. & Poedts, S., European Planetary Science Congress 2007, p. 755
4. Quantifying Shear-induced Wave Transformations in the Solar Wind [11]
   Gogoberidze, Grigol, Rogava, Andria & Poedts, Stefaan, ApJ, 664, 549
5. Comparison between 2.5D and 3D simulations of coronal mass ejections [24]
   Jacobs, C., van der Holst, B. & Poedts, S., A&A, 470, 359
6. Numerical simulations of the initiation and the IP evolution of coronal mass ejections [1]
   Jacobs, C., Poedts, S., van der Holst, B., Dubey, G. & Keppens, R., Flows, Boundaries, and Interactions (Editors: Dumitrache, Cristiana & Popescu, Nedelia A.), American Institute of Physics Conference Series, 934, p. 101
7. Analysis of the effect of neutral flow on the waves in the solar photosphere [4]
   Petrović, D., Vranjes, J. & Poedts, S., A&A, 461, 277
8. Simulating CME Initiation and Evolution: State-of-the-art [0]
   Poedts, S., van der Holst, B., Jacobs, C., Chané, E., Dubey, G. & Kimpe, D., Space Weather : Research Towards Applications in Europe 2nd European Space Weather Week (ESWW2) (Editors: Lilensten, Jean), Astrophysics and Space Science Library, 344, p. 39
9. Overreflection and Generation of Gravito-Alfvén Waves in Solar-Type Stars [4]
   Rogava, Andria, Gogoberidze, Grigol & Poedts, Stefaan, ApJ, 664, 1221
10. Plasma flows around magnetic obstacles in the solar wind [4]
    Romashets, E. & Poedts, S., A&A, 475, 1093
11. Modeling of the three-dimensional motion of toroidal magnetic clouds in the inner heliosphere [6]
    Romashets, E., Vandas, M. & Poedts, S., A&A, 466, 357
12. Unstable drift mode driven by shear plasma flow in solar spicules [22]
    Saleem, H., Vranjes, J. & Poedts, S., A&A, 471, 289
13. On the shear flow instability and its applications to multicomponent plasmas [36]
    Saleem, H., Vranjes, J. & Poedts, S., Physics of Plasmas, 14, 072104
14. Amplification of compressional magnetohydrodynamic waves in systems with forced entropy oscillations [12]
    Shergelashvili, Bidzina M., Maes, Christian, Poedts, Stefaan & Zaqarashvili, Teimuraz V., Physical Review E, 76, 046404
15. Modifications to the resistive MHD spectrum due to changes in the equilibrium [13]
    Van Doorsselaere, T. & Poedts, S., Plasma Physics and Controlled Fusion, 49, 261
16. Observational evidence favors a resistive wave heating mechanism for coronal loops over a viscous phenomenon [31]
    Van Doorsselaere, T., Andries, J. & Poedts, S., A&A, 471, 311
17. Comment on ``Heating of the Solar Corona by Dissipative Alfvén Solitons'' [10]
    Vranjes, J., Poedts, S. & Pandey, B. P., Physical Review Letters, 98, 049501
18. Electromagnetic ion acoustic perturbations in spatially varying plasma [10]
    Vranjes, J., Saleem, H. & Poedts, S., Physics of Plasmas, 14, 034504
19. On the properties of electrostatic drift and sound modes in radially and axially inhomogeneous bounded plasmas [8]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 14, 112106
20. Gas acoustic and ion acoustic waves in partially ionized plasmas with magnetized electrons [9]
    Vranjes, J., Pandey, B. P. & Poedts, S., Physics of Plasmas, 14, 032106
21. Commission 49: Interplanetary Plasma and Heliosphere [0]
    Webb, David F., Bougeret, Jean-Louis, Cane, Hilary V., Cramer, Neil F., Kahler, Stephen W., Kojima, Masayoshi, Sanahuja, Blai, Vandas, Marek, Verheest, Frank & von Steiger, Rudolf, Transactions of the International Astronomical Union, Series A, 26A, 103
22. Simulation of a Breakout Coronal Mass Ejection in the Solar Wind [59]
    van der Holst, B., Jacobs, C. & Poedts, S., ApJ, 671, L77

2006

1. Seismology of Coronal Loops Using the Period and Damping of Quasi-Mode Kink Oscillations [0]
   Arregui, I., Andries, J., Van Doorsselaere, T., Goossens, M. & Poedts, S., SOHO-17. 10 Years of SOHO and Beyond (Editors: Lacoste, H. & Ouwehand, L.), ESA Special Publication, 617, p. 81
2. Quasi-mode damping in two-dimensional fully non-uniform coronal loops [5]
   Arregui, I., Van Doorsselaere, T., Andries, J., Goossens, M. & Poedts, S., Philosophical Transactions of the Royal Society of London Series A, 364, 529
3. Inverse and normal coronal mass ejections: evolution up to 1 AU [58]
   Chané, E., van der Holst, B., Jacobs, C., Poedts, S. & Kimpe, D., A&A, 447, 727
4. CME Modeling: An a Posteriori Approach [0]
   Chané, E., Poedts, S. & van der Holst, B., SOHO-17. 10 Years of SOHO and Beyond (Editors: Lacoste, H. & Ouwehand, L.), ESA Special Publication, 617, p. 120
5. Simulations of the Onset and the Evolution of Coronal Mass Ejections [0]
   De Groof, A. & Poedts, S., Fusion Science and Technology, 49, 477
6. On the Effect of the Background Solar Wind on CME's Initiated by Flux Emergence [0]
   Dubey, G., Poedts, S., van der Holst, B. & Gryp, M., SOHO-17. 10 Years of SOHO and Beyond (Editors: Lacoste, H. & Ouwehand, L.), ESA Special Publication, 617, p. 125
7. The initiation of coronal mass ejections by magnetic flux emergence [18]
   Dubey, G., van der Holst, B. & Poedts, S., A&A, 459, 927
8. Initiation of CMEs by Magnetic Flux Emergence [6]
   Dubey, Govind, van der Holst, Bart & Poedts, Stefaan, Journal of Astrophysics and Astronomy, 27, 159
9. The effect of the solar wind on CME triggering by magnetic foot point shearing [46]
   Jacobs, C., Poedts, S. & van der Holst, B., A&A, 450, 793
10. 3D Evolution of a "Density-Driven" CME Event [0]
    Jacobs, C., Poedts, S. & van der Holst, B., SOHO-17. 10 Years of SOHO and Beyond (Editors: Lacoste, H. & Ouwehand, L.), ESA Special Publication, 617, p. 140
11. On the Motion of Toroidal Magnetic Clouds in the Solar Corona and Inner Heliosphere [1]
    Romashets, E., Vandas, M. & Poedts, S., SOHO-17. 10 Years of SOHO and Beyond (Editors: Lacoste, H. & Ouwehand, L.), ESA Special Publication, 617, p. 144
12. On some properties of linear and nonlinear waves in pair-ion plasmas [56]
    Saleem, H., Vranjes, J. & Poedts, S., Physics Letters A, 350, 375
13. Nonmodal Cascade in the Compressible Solar Atmosphere: Self-Heating, an Alternative Way to Enhance Wave Heating [27]
    Shergelashvili, Bidzina M., Poedts, Stefaan & Pataraya, Avtandil D., ApJ, 642, L73
14. Unstable ion sound in plasmas with drifting electrons [7]
    Vranjes, J. & Poedts, S., European Physical Journal D, 40, 257
15. Growing drift-Alfvén modes in collisional solar plasma [20]
    Vranjes, J. & Poedts, S., A&A, 458, 635
16. Properties of the acoustic mode in partially ionized and dusty plasmas [16]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 13, 052103
17. Instability of electrostatic modes in partially ionized plasma [17]
    Vranjes, J. & Poedts, S., Physics Letters A, 348, 346
18. The effects of inelastic collisions on waves in partially ionized plasma [4]
    Vranjes, J., Kono, M., Petrovic, D., Poedts, S., Okamoto, A., Yoshimura, S. & Tanaka, M. Y., Plasma Sources Science Technology, 15, S1
19. Collisional instability of the drift wave in multi-component plasmas [8]
    Vranjes, J., Pandey, B. P. & Poedts, S., Planetary and Space Science, 54, 695
20. Unstable kinetic Alfvén wave in partially ionized plasma [6]
    Vranjes, J., Petrovic, D., Poedts, S., Kono, M. & Čadež, V. M., Planetary and Space Science, 54, 641
21. Comment on ‘Effect of ionization on ion acoustic solitary waves in a collisional dusty plasma’ (<em>J. Plasma Phys</em>. 71, 519 (2005)) [0]
    Vranjes, J., Pandey, B. P. & Poedts, S., Journal of Plasma Physics, 72, 617
22. Fluid modeling of the electron flow driven ion acoustic mode in a collisional plasma with magnetized electrons [13]
    Vranjes, J., Tanaka, M. Y. & Poedts, S., Physics of Plasmas, 13, 122103
23. Ion Sound in Highly Collisional, Partially Ionized Plasma [0]
    Vranjes, J. & Poedts, S., SOHO-17. 10 Years of SOHO and Beyond (Editors: Lacoste, H. & Ouwehand, L.), ESA Special Publication, 617, p. 116
24. Properties of the acoustic mode in partially ionized and dusty plasmas [0]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 13, 052104
25. Drift-Alfvén eigenmodes in inhomogeneous plasma [6]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 13, 032107
26. Time Dependent Simulations of 2D Coronal Loop Models [0]
    van Doorsselaere, T., Poedts, S., Andries, J. & Arregui, I., SOHO-17. 10 Years of SOHO and Beyond (Editors: Lacoste, H. & Ouwehand, L.), ESA Special Publication, 617, p. 113

2005

1. Seismology of Coronal Loops Using Resonant Absorption [0]
   Arregui, I., van Doorsselaere, T., Andries, J., Goossens, M. & Poedts, S., The Dynamic Sun: Challenges for Theory and Observations (Editors: Danesy, D., Poedts, S., de Groof, A. & Andries, J.), ESA Special Publication, 11, p. 21.1
2. CME Modeling: the a Posteriori Approach [0]
   Chané, E., Poedts, S. & van der Holst, B., The Dynamic Sun: Challenges for Theory and Observations (Editors: Danesy, D., Poedts, S., de Groof, A. & Andries, J.), ESA Special Publication, 11, p. 154.1
3. On the effect of the initial magnetic polarity and of the background wind on the evolution of CME shocks [63]
   Chané, E., Jacobs, C., van der Holst, B., Poedts, S. & Kimpe, D., A&A, 432, 331
4. Triggering CMEs by Magnetic Flux Emergence [1]
   Dubey, G., Poedts, S. & van der Holst, B., Solar Wind 11/SOHO 16, Connecting Sun and Heliosphere (Editors: Fleck, B., Zurbuchen, T. H. & Lacoste, H.), ESA Special Publication, 592, p. 637
5. Solar coronal loop oscillations: theory of resonantly damped oscillations and comparison with observations [3]
   Goossens, M., Andries, J., Arregui, I., Doorsselaere, T. V. & Poedts, S., Magnetic Fields in the Universe: From Laboratory and Stars to Primordial Structures. (Editors: de Gouveia dal Pino, Elisabete M., Lugones, Germán & Lazarian, Alexander), American Institute of Physics Conference Series, 784, p. 114
6. Foreword: Computing in Space and Astrophysical Plasmas [1]
   Goossens, Marcel, Poedts, Stefaan, Voitenko, Yuriy & Chian, Abraham C.-L., Space Science Reviews, 121, 1
7. On the effect of the background wind on the evolution of interplanetary shock waves [41]
   Jacobs, C., Poedts, S., Van der Holst, B. & Chané, E., A&A, 430, 1099
8. CME Triggering by Magnetic Footpoint Shearing [1]
   Jacobs, C., Poedts, S. & van der Holst, B., Solar Wind 11/SOHO 16, Connecting Sun and Heliosphere (Editors: Fleck, B., Zurbuchen, T. H. & Lacoste, H.), ESA Special Publication, 592, p. 641
9. Triggering CMES by Magnetic Foot Point Shearing: a Parameter Study [1]
   Jacobs, C., Poedts, S. & van der Holst, B., The Dynamic Sun: Challenges for Theory and Observations (Editors: Danesy, D., Poedts, S., de Groof, A. & Andries, J.), ESA Special Publication, 11, p. 158.1
10. Collisional Drift Instability in Plasmas with Inelastic Collisions [0]
    Petrovic, D., Vranjes, J. & Poedts, S., The Dynamic Sun: Challenges for Theory and Observations (Editors: Danesy, D., Poedts, S., de Groof, A. & Andries, J.), ESA Special Publication, 11, p. 67.1
11. Effects of ionization on the collisional streaming instability [5]
    Petrović, D., Vranjes, J. & Poedts, S., Physics of Plasmas, 12, 112103
12. Quantitative Study of Initiation and Evolution of CMEs in Different Wind Models [1]
    Poedts, S., Chané, E., van der Holst, B., Jacobs, C., Dubey, G. & Kimpe, D., Solar Wind 11/SOHO 16, Connecting Sun and Heliosphere (Editors: Fleck, B., Zurbuchen, T. H. & Lacoste, H.), ESA Special Publication, 592, p. 301
13. Non-Modal Self-Heating of the Solar Atmosphere: AN Alternative way to Enhance the Wave Heating Process [0]
    Shergelashvili, B. M., Poedts, S. & Pataraya, A. D., The Dynamic Sun: Challenges for Theory and Observations (Editors: Danesy, D., Poedts, S., de Groof, A. & Andries, J.), ESA Special Publication, 11, p. 98.1
14. On the effect of the inhomogeneous subsurface flows on the high degree solar p-modes [6]
    Shergelashvili, B. M. & Poedts, S., A&A, 438, 1083
15. ``Swing Absorption'' of fast magnetosonic waves in inhomogeneous media [14]
    Shergelashvili, B. M., Zaqarashvili, T. V., Poedts, S. & Roberts, B., A&A, 429, 767
16. Transient Amplification of Disturbances in the Solar Atmosphere: a Mechanism for CME Initiation? [0]
    Shergelashvili, B. M., Poedts, S. & Pataraya, A. D., The Dynamic Sun: Challenges for Theory and Observations (Editors: Danesy, D., Poedts, S., de Groof, A. & Andries, J.), ESA Special Publication, 11, p. 165.1
17. Electrostatic Modes in Partially Ionized Plasma [0]
    Vranjes, J. & Poedts, S., The Dynamic Sun: Challenges for Theory and Observations (Editors: Danesy, D., Poedts, S., de Groof, A. & Andries, J.), ESA Special Publication, 11, p. 68.1
18. Low Frequency Waves in Spatially Bounded Plasma [0]
    Vranjes, J. & Poedts, S., The Dynamic Sun: Challenges for Theory and Observations (Editors: Danesy, D., Poedts, S., de Groof, A. & Andries, J.), ESA Special Publication, 11, p. 104.1
19. Low-frequency waves in bounded streaming plasma [10]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 12, 064501
20. Multiwavelength Analysis of Downflows Along AN Off-Limb Loop [0]
    de Groof, A., Müller, D. A. N. & Poedts, S., The Dynamic Sun: Challenges for Theory and Observations (Editors: Danesy, D., Poedts, S., de Groof, A. & Andries, J.), ESA Special Publication, 11, p. 29.1
21. Downflows Along AN Off-Limb Loop Seen both in 30.4NM and Hα [0]
    de Groof, A., Müller, D. A. N. & Poedts, S., Chromospheric and Coronal Magnetic Fields (Editors: Innes, D. E., Lagg, A. & Solanki, S. A.), ESA Special Publication, 596, p. 36.1
22. Detailed comparison of downflows seen both in EIT 30.4 nm and Big Bear Hα movies [58]
    de Groof, A., Bastiaensen, C., Müller, D. A. N., Berghmans, D. & Poedts, S., A&A, 443, 319
23. Dynamics of Coronal Loop Oscillations [0]
    van Doorsselaere, T., Arregui, I., Andries, J., Goossens, M. & Poedts, S., Chromospheric and Coronal Magnetic Fields (Editors: Innes, D. E., Lagg, A. & Solanki, S. A.), ESA Special Publication, 596, p. 44.1
24. Building a Time Dependent Code to Simulate Oscillations of Line-Tied Coronal Loops [0]
    van Doorsselaere, T., Poedts, S., Arregui, I. & Andries, J., The Dynamic Sun: Challenges for Theory and Observations (Editors: Danesy, D., Poedts, S., de Groof, A. & Andries, J.), ESA Special Publication, 11, p. 83.1
25. Dynamics of Coronal Loop Oscillations Recent Improvements and Computational Aspects [1]
    van Doorsselaere, T., Arregui, I., Andries, J., Goossens, M. & Poedts, S., Space Science Reviews, 121, 79
26. Modelling of Solar Wind, CME Initiation and CME Propagation [18]
    van der Holst, B., Poedts, S., Chané, E., Jacobs, C., Dubey, G. & Kimpe, D., Space Science Reviews, 121, 91

2004

1. Detection of Long Periodwaves in the Polar Coronal Holes [0]
   Banerjee, D., O'Shea, E., Doyle, J. G. & Poedts, S., SOHO 15 Coronal Heating (Editors: Walsh, R. W., Ireland, J., Danesy, D. & Fleck, B.), ESA Special Publication, 575, p. 136
2. Active Region Oscillations as Observed by CDS, EIT and TRACE [0]
   Banerjee, D., O'Shea, E., de Groof, A. & Poedts, S., SOHO 13 Waves, Oscillations and Small-Scale Transients Events in the Solar Atmosphere: Joint View from SOHO and TRACE (Editors: Lacoste, H.), ESA Special Publication, 547, p. 39
3. Intensity variations in EIT shutterless mode: Waves or flows? [73]
   De Groof, A., Berghmans, D., van Driel-Gesztelyi, L. & Poedts, S., A&A, 415, 1141
4. Principles of Magnetohydrodynamics [351]
   Goedbloed, J. P. Hans & Poedts, Stefaan,
5. Coronal MHD Waves and Theoretical Constraints of Wave Heating [2]
   Poedts, S. & de Groof, A., SOHO 15 Coronal Heating (Editors: Walsh, R. W., Ireland, J., Danesy, D. & Fleck, B.), ESA Special Publication, 575, p. 62
6. Transient shear instability of differentially rotating and self-gravitating dusty plasma [6]
   Rogava, Andria D., Poedts, Stefaan & Osmanov, Zaza, Physics of Plasmas, 11, 1655
7. Streaming ion instability in nonuniform magnetized plasmas and nonlinear structures [0]
   Saleem, H., Vranjes, J. & Poedts, S., Physics Letters A, 328, 65
8. Is the Solar Corona Nonmodally Self-Heated [2]
   Shergelashvili, B. M., Rogava, A. D. & Poedts, S., SOHO 15 Coronal Heating (Editors: Walsh, R. W., Ireland, J., Danesy, D. & Fleck, B.), ESA Special Publication, 575, p. 437
9. The Mechanism of Swing Absorption of Fast Magnetosonic Waves in Inhomogeneous Media [0]
   Shergelashvili, B. M., Zaqarashvili, T. V., Poedts, S. & Roberts, B., SOHO 15 Coronal Heating (Editors: Walsh, R. W., Ireland, J., Danesy, D. & Fleck, B.), ESA Special Publication, 575, p. 431
10. On the Effect of Non-Uniform Subsurface Flows on High Degree p-Modes [0]
    Shergelashvili, B. M. & Poedts, S., SOHO 13 Waves, Oscillations and Small-Scale Transients Events in the Solar Atmosphere: Joint View from SOHO and TRACE (Editors: Lacoste, H.), ESA Special Publication, 547, p. 87
11. The effect of curvature on quasi-modes in coronal loops [113]
    Van Doorsselaere, T., Debosscher, A., Andries, J. & Poedts, S., A&A, 424, 1065
12. Damping of Coronal Loop Oscillations: Calculation of Resonantly Damped Kink Oscillations of One-dimensional Nonuniform Loops [153]
    Van Doorsselaere, T., Andries, J., Poedts, S. & Goossens, M., ApJ, 606, 1223
13. Ion temperature gradient instability in a dusty plasma [22]
    Vranjes, J., Saleem, H. & Poedts, S., Physical Review E, 69, 056404
14. Analysis of low-frequency waves in inhomogeneous and bounded plasmas [28]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 11, 891
15. The image charge effects on plasma waves in the presence of neutral dust grains [2]
    Vranjes, J. & Poedts, S., Physics Letters A, 323, 439
16. Waves propagating along a density gradient in a dusty plasma [3]
    Vranjes, J. & Poedts, S., Physics Letters A, 320, 423
17. Electrostatic waves in bounded dusty magnetoplasma [14]
    Vranjes, J. & Poedts, S., Physics of Plasmas, 11, 2178
18. Electrostatic perturbations in partially ionized plasma with the effects of ionization and recombination [9]
    Vranjes, J., Tanaka, M. Y., Kono, M. & Poedts, S., Physics of Plasmas, 11, 4188
19. Response to ``Comment on `Ion-acoustic waves in dusty plasma with charge fluctuations' '' [Phys. Plasmas 11, 849 (2004)] [0]
    Vranješ, J., Pandey, B. P. & Poedts, S., Physics of Plasmas, 11, 852
20. The effects of image charge on waves in dusty plasma [0]
    Vranješ, J. & Poedts, S., Plasmas in the Laboratory and in the Universe: New Insights and New Challenges (Editors: Bertin, Giuseppe, Farina, Daniela & Pozzoli, Roberto), American Institute of Physics Conference Series, 703, p. 96
21. Waves in bounded dusty plasma [1]
    Vranješ, J. & Poedts, S., Plasmas in the Laboratory and in the Universe: New Insights and New Challenges (Editors: Bertin, Giuseppe, Farina, Daniela & Pozzoli, Roberto), American Institute of Physics Conference Series, 703, p. 92
22. Comment on: “Theory of vortex flows in partially ionized magnetoplasmas” [Phys. Lett. A 326 (2004) 267] [0]
    Vranješ, J., Tanaka, M. Y., Kono, M. & Poedts, S., Physics Letters A, 329, 162
23. Intensity Variations in EIT Shutterless Mode: Waves or Flows? [0]
    de Groof, A., Berghmans, D., van Driel-Gesztelyi, L. & Poedts, S., SOHO 13 Waves, Oscillations and Small-Scale Transients Events in the Solar Atmosphere: Joint View from SOHO and TRACE (Editors: Lacoste, H.), ESA Special Publication, 547, p. 245
24. Quasi-Modes on Curved Solar Coronal Loops [1]
    van Doorsselaere, T., Debosscher, A. & Poedts, S., SOHO 13 Waves, Oscillations and Small-Scale Transients Events in the Solar Atmosphere: Joint View from SOHO and TRACE (Editors: Lacoste, H.), ESA Special Publication, 547, p. 525
25. The Effect of Curvature on Quasi-Modes in Coronal Loops [0]
    van Doorsselaere, T., Debosscher, A., Andries, J. & Poedts, S., SOHO 15 Coronal Heating (Editors: Walsh, R. W., Ireland, J., Danesy, D. & Fleck, B.), ESA Special Publication, 575, p. 448

2003

1. Computer simulations of solar plasmas [7]
   Goedbloed, J. P., Keppens, R. & Poedts, S., Space Science Reviews, 107, 63
2. Variation of coronal line widths on and off the disk [32]
   O'Shea, E., Banerjee, D. & Poedts, S., A&A, 400, 1065
3. Jeans instability of an inhomogeneous streaming dusty plasma [12]
   Pandey, B. P., van Dere Holst, B., Vranjes, J. & Poedts, S., Pramana, 61, 109
4. Simulation of shock waves in the interplanetary medium [1]
   Poedts, S., van der Holst, B., Chattopadhyay, I., Banerjee, D., van Lier, T. & Keppens, R., Solar Variability as an Input to the Earth's Environment (Editors: Wilson, Andrew), ESA Special Publication, 535, p. 603
5. Interchange mode in the presence of dust [6]
   Vranješ, J., Tanaka, M. Y., Kono, M. & Poedts, S., Physical Review E, 67, 026410

2002

1. On the nature of umbral oscillations: theory and observation by CDS/SoHO [0]
   Banerjee, D., O'Shea, E., Goossens, M., Poedts, S. & Doyle, J. G., Solar Variability: From Core to Outer Frontiers (Editors: Wilson, A.), ESA Special Publication, 1, p. 427
2. On the theory of MAG waves and a comparison with sunspot observations from CDS/SoHO [13]
   Banerjee, D., O'Shea, E., Goossens, M., Doyle, J. G. & Poedts, S., A&A, 395, 263
3. Slow MAG waves in the sunspot umbra as observed by CDS/SOHO [0]
   Banerjee, D., O'Shea, E., Doyle, J. G., Goossens, M. & Poedts, S., SOLMAG 2002. Proceedings of the Magnetic Coupling of the Solar Atmosphere Euroconference (Editors: Sawaya-Lacoste, Huguette), ESA Special Publication, 505, p. 187
4. Helicity loading and dissipation: The helicity budget of ar 7978 from the cradle to the grave [0]
   Driel-Gesztelyi, L. van, Démoulin, P., Mandrini, C. H., Plunkett, S., Thompson, B., Kővári, Zs., Aulanier, G., Young, A., López Fuentes, M. & Poedts, S., Cospar, 13, 143
5. Equilibrium Properties of a Gravitating Dusty Plasma [9]
   Pandey, B. P., Vranješ, J., Shukla, P. K. & Poedts, S., Physica Scripta, 66, 269
6. The Pulsational Mode in the Presence of Dust Charge Fluctuations [26]
   Pandey, B. P., Vranješ, J., Poedts, S. & Shukla, P. K., Physica Scripta, 65, 513
7. Does spiral galaxy IC 342 exhibit shear induced wave transformations!? [5]
   Poedts, S. & Rogava, A. D., A&A, 385, 32
8. Numerical modeling of CME initiation and propagation [5]
   Poedts, S., van der Holst, B., de Sterck, H., van Driel-Gesztelyi, L., Csík, A., Milesi, A. & Deconinck, H., Solspa 2001, Proceedings of the Second Solar Cycle and Space Weather Euroconference (Editors: Sawaya-Lacoste, Huguette), ESA Special Publication, 477, p. 263
9. MHD waves and heating of the solar corona [6]
   Poedts, Stefan, SOLMAG 2002. Proceedings of the Magnetic Coupling of the Solar Atmosphere Euroconference (Editors: Sawaya-Lacoste, Huguette), ESA Special Publication, 505, p. 273
10. Ion-acoustic waves in dusty plasma with charge fluctuations [18]
    Vranješ, J., Pandey, B. P. & Poedts, S., Physics of Plasmas, 9, 1464
11. A dipolar vortex in a magnetized pair plasma containing nonuniform flows [0]
    Vranješ, J., Pandey, B. P., Shukla, P. K. & Poedts, S., Physics of Plasmas, 9, 806
12. Comment on ``Effect of flow profile on low frequency drift-type waves in a dusty plasma'' [Phys. Plasmas 8, 3150 (2001)] [1]
    Vranješ, J., Pandey, B. P. & Poedts, S., Physics of Plasmas, 9, 1481
13. Three-Wave Interaction in a Self-Gravitating Fluid [6]
    Vranješ, J. & Poedts, S., Physical Review Letters, 89, 131102
14. Analytical Description of a Neutral-Induced Tripole Vortex in a Plasma [28]
    Vranješ, J., Okamoto, A., Yoshimura, S., Poedts, S., Kono, M. & Tanaka, M. Y., Physical Review Letters, 89, 265002
15. Electron acoustic wave in a dusty plasma [5]
    Vranješ, J., Saleem, H. & Poedts, S., Planetary and Space Science, 50, 807
16. Helicity Loading and Dissipation: The Helicity Budget of AR 7978 from the Cradle to the Grave [0]
    van Driel-Gesztelyi, L., Démoulin, P., Mandrini, C. H., Plunkett, S., Thompson, B., Kövári, Zs., Aulanier, G., Young, A., López Fuentes, M. & Poedts, S., Multi-Wavelength Observations of Coronal Structure and Dynamics (Editors: Martens, P. C. H. & Cauffman, D.), 10, p. 143
17. Magnetic build-up and precursors of CMEs [5]
    van Driel-Gesztelyi, Lidia, Schmieder, Brigitte & Poedts, Stefaan, Solspa 2001, Proceedings of the Second Solar Cycle and Space Weather Euroconference (Editors: Sawaya-Lacoste, Huguette), ESA Special Publication, 477, p. 47
18. CME shock warps coronal streamer - observation and MHD simulation [12]
    van der Holst, B., van Driel-Gesztelyi, L. & Poedts, S., Solar Variability: From Core to Outer Frontiers (Editors: Wilson, A.), ESA Special Publication, 1, p. 71
19. Axisymmetric magnetized winds and stellar spin-down [5]
    van der Holst, B., Banerjee, D., Keppens, R. & Poedts, S., Solar Variability: From Core to Outer Frontiers (Editors: Wilson, A.), ESA Special Publication, 1, p. 75

2001

1. Spatial aspect of wave transformations in astrophysical flows [16]
   Bodo, G., Poedts, S., Rogava, A. & Rossi, P., A&A, 374, 337
2. Monotone Residual Distribution Schemes for the Ideal Magnetohydrodynamic Equations on Unstructured Grids [3]
   Csík, Árpád, Deconinck, Herman & Poedts, Stefaan, AIAA Journal, 39, 1532
3. A Survey of Field-Aligned Mach Number and Plasma Beta in the Solar Wind [3]
   De Keyser, Johan, Roth, Michel, De Sterck, Hans & Poedts, Stefaan, Space Science Reviews, 97, 201
4. Disintegration and reformation of intermediate-shock segments in three-dimensional MHD bow shock flows [9]
   De Sterck, H. & Poedts, S., Journal of Geophysical Research, 106, 30023
5. Stationary Two-Dimensional Magnetohydrodynamic Flows with Shocks: Characteristic Analysis and Grid Convergence Study [14]
   De Sterck, H., Csík, A., Abeele, D. Vanden, Poedts, S. & Deconinck, H., Journal of Computational Physics, 166, 28
6. Shear Induced Phenomena in Dusty Plasma Flows [1]
   Khujadze, George R., Poedts, Stefaan & Rogava, Andria D., Astrophysics and Space Science, 277, 135
7. 3D MHD shocks caused by CMEs/magnetic clouds [0]
   Poedts, S., de Sterck, H., van der Holst, B., Pandey, B. P., Csík, Á. & Deconinck, H., Space Plasma Simulation (Editors: Büchner, J., Dum, C. T. & Scholer, M.), p. 324
8. Slow magnetoacoustic waves in coronal loops: EIT and TRACE [139]
   Robbrecht, E., Verwichte, E., Berghmans, D., Hochedez, J. F., Poedts, S. & Nakariakov, V. M., A&A, 370, 591
9. Linear and nonlinear electrostatic modes in a nonuniform magnetized electron plasma [2]
   Vranješ, J., Shukla, P. K., Kono, M. & Poedts, S., Physics of Plasmas, 8, 3165
10. Skin Size Vortices in Streaming Plasmas [0]
    Vranješ, J., Shukla, P. K. & Poedts, S., Physica Scripta Volume T, 98, 155
11. Effects of dust charge fluctuations on current-driven dust-ion-acoustic waves [29]
    Vranješ, J., Pandey, B. P. & Poedts, S., Physical Review E, 64, 066404
12. Velocity shear driven electron skin size vortices [3]
    Vranješ, J., Shukla, P. K. & Poedts, S., Physics of Plasmas, 8, 3913
13. The effect of shear flows on the Rayleigh-Taylor unstable magnetopause [0]
    van der Holst, B., Pandey, B. P. & Poedts, S., Space Plasma Simulation (Editors: Büchner, J., Dum, C. T. & Scholer, M.), p. 384

2000

1. Acoustic phenomena in electrostatic dusty plasma shear flows [8]
   Poedts, Stefaan, Khujadze, George R. & Rogava, Andria D., Physics of Plasmas, 7, 3204
2. Nonmodal phenomena in differentially rotating dusty plasmas [0]
   Poedts, Stefaan & Rogava, Andria D., Waves in Dusty, Solar, and Space Plasmas (Editors: Verheest, F., Goossens, M., Hellberg, M. A. & Bharuthram, R.), American Institute of Physics Conference Series, 537, p. 76
3. Slow magnetoacoustic waves in coronal loops: EIT vs TRACE [1]
   Robbrecht, E., Verwichte, E., Berghmans, D., Hochedez, J. F. & Poedts, S., Waves in Dusty, Solar, and Space Plasmas (Editors: Verheest, F., Goossens, M., Hellberg, M. A. & Bharuthram, R.), American Institute of Physics Conference Series, 537, p. 271
4. Shear-driven wave oscillations in astrophysical flux tubes [28]
   Rogava, A. D., Poedts, S. & Mahajan, S. M., A&A, 354, 749
5. Intermediate Shocks in Three-Dimensional Magnetohydrodynamic Bow-Shock Flows with Multiple Interacting Shock Fronts [23]
   de Sterck, H. & Poedts, S., Physical Review Letters, 84, 5524
6. Disintegration and reformation of intermediate shock segments in 3D MHD bow shock flows [2]
   de Sterck, H. & Poedts, S., Waves in Dusty, Solar, and Space Plasmas (Editors: Verheest, F., Goossens, M., Hellberg, M. A. & Bharuthram, R.), American Institute of Physics Conference Series, 537, p. 232

1999

1. Characteristic analysis of a complex two-dimensional magnetohydrodynamic bow shock flow with steady compound shocks [12]
   De Sterck, H., Low, B. C. & Poedts, S., Physics of Plasmas, 6, 954
2. Stationary slow shocks in the magnetosheath for solar wind conditions with β<2/γ: Three-dimensional MHD simulations [15]
   De Sterck, H. & Poedts, S., Journal of Geophysical Research, 104, 22401
3. Velocity Shear Induced Phenomena in Solar Atmosphere [9]
   Poedts, S., Rogava, A. D. & Mahajan, S. M., Space Science Reviews, 87, 295
4. Waves in the Transition Region and Corona: a Theorist's View [1]
   Poedts, S., Magnetic Fields and Solar Processes (Editors: Wilson, A. & et al.), ESA Special Publication, 448, p. 167
5. 3D Nonlinear MHD Wave Heating of Coronal Loops^CD [0]
   Poedts, S., Keppens, R. & Beliën, A. J. C., Numerical Astrophysics (Editors: Miyama, Shoken M., Tomisaka, Kohji & Hanawa, Tomoyuki), Astrophysics and Space Science Library, 240, p. 319
6. Magnetohydrodynamics Stability Analysis of the KT-2 Tokamak Plasma [0]
   Poedts, Stefaan, De Ploey, Arnold, Goedbloed, Hans, Hong, Bong Guen & Kim, Sun Kyu, Fusion Technology, 35, 18
7. Slow Magnetoacoustic Waves in Coronal Loops? [10]
   Robbrecht, E., Berghmans, D., Nakariakov, V. & Poedts, S., 8th SOHO Workshop: Plasma Dynamics and Diagnostics in the Solar Transition Region and Corona (Editors: Vial, J.-C. & Kaldeich-Schü, B.), ESA Special Publication, 446, p. 575
8. What May Spring Up in Solar Tornadoes? [0]
   Rogava, A. & Poedts, S., Magnetic Fields and Solar Processes (Editors: Wilson, A. & et al.), ESA Special Publication, 448, p. 355
9. Are galactic magnetohydrodynamic waves coupled? [16]
   Rogava, Andria D., Poedts, Stefaan & Heirman, Stijn, MNRAS, 307, L31
10. Field-aligned magnetohydrodynamic bow shock flows in the switch-on regime. Parameter study of the flow around a cylinder and results for the axi-symmetrical flow over a sphere [35]
    de Sterck, H. & Poedts, S., A&A, 343, 641
11. Complex Interacting Shock Fronts Induced by Fast CMEs [1]
    de Sterck, H. & Poedts, S., Magnetic Fields and Solar Processes (Editors: Wilson, A. & et al.), ESA Special Publication, 448, p. 935

1998

1. CASTOR: Normal-Mode Analysis of Resistive MHD Plasmas [127]
   Kerner, W., Goedbloed, J. P., Huysmans, G. T. A., Poedts, S. & Schwarz, E., Journal of Computational Physics, 142, 271
2. Shear-flow-induced Wave Couplings In The Solar Wind [48]
   Poedts, Stefaan, Rogava, Andria D. & Mahajan, Swadesh M., ApJ, 505, 369
3. Wave heating of coronal arcades driven by toroidally polarised footpoint motions. Stationary behaviour in dissipative MHD [8]
   Tirry, W. J. & Poedts, S., A&A, 329, 754
4. Complex magnetohydrodynamic bow shock topology in field-aligned low-β flow around a perfectly conducting cylinder [42]
   de Sterck, H., Low, B. C. & Poedts, S., Physics of Plasmas, 5, 4015
5. Dynamics of hot filaments in a tokamak plasma [9]
   de Sterck, H., Poedts, S. & Goedbloed, J. P., Journal of Plasma Physics, 59, 277

1997

1. Continuous magnetohydrodynamic spectra of two-dimensional coronal magnetostatic flux tubes. [14]
   Belieen, A. J. C., Poedts, S. & Goedbloed, J. P., A&A, 322, 995
2. Two-dimensional equilibrium in coronal magnetostatic flux tubes: an accurate equilibrium solver [7]
   Beliën, A. J. C., Poedts, S. & Goedbloed, J. P., Computer Physics Communications, 106, 21
3. Slow Magnetosonic Waves and Instabilities in Expanded Flux Tubes Anchored in Chromospheric/Photospheric Regions [2]
   Beliën, A. J. C., Poedts, S. & Goedbloed, J. P., Fifth SOHO Workshop: The Corona and Solar Wind Near Minimum Activity (Editors: Wilson, A.), ESA Special Publication, 404, p. 193
4. Calculating magnetohydrodynamic flow spectra [18]
   Nijboer, R. J., Holst, B. v. d., Poedts, S. & Goedbloed, J. P., Computer Physics Communications, 106, 39
5. MHD wave heating of coronal loops [0]
   Poedts, S., Tirry, W., Berghmans, D. & Goossens, M., Joint European and National Astronomical Meeting (Editors: Hadjidemetrioy, John D. & Seiradakis, John H.), p. 54
6. Nonlinear MHD Simulations of Wave Dissipation in Flux Tubes [29]
   Poedts, S., Tóth, G., Beliën, A. J. C. & Goedbloed, J. P., Solar Physics, 172, 45
7. Nonlinear wave heating of solar coronal loops. [22]
   Poedts, S. & Goedbloed, J. P., A&A, 321, 935
8. Direct excitation of resonant torsional Alfven waves by footpoint motions. [66]
   Ruderman, M. S., Berghmans, D., Goossens, M. & Poedts, S., A&A, 320, 305

1996

1. Calculation of Soft X-ray Images from MHD Simulations of Heating of Coronal Loops [0]
   Belien, A. J. C., Poedts, S. & Goedbloed, J. P., IAU Colloquium 153: Magnetodynamic Phenomena in the Solar Atmosphere - Prototypes of Stellar Magnetic Activity (Editors: Uchida, Yutaka, Kosugi, Takeo & Hudson, Hugh S.), p. 423
2. Visualization of resonant absorption in solar coronal loops by simulation of soft X-ray images. [4]
   Belien, A. J. C., Poedts, S., Spoelder, H. J. W., Leenders, R. & Goedbloed, J. P., Computers in Physics, 10, 573
3. Magnetohydrodynamic Continua and Stratification Induced Alfvén Eigenmodes in Coronal Magnetic Loops [14]
   Beliën, A. J. C., Poedts, S. & Goedbloed, J. P., Physical Review Letters, 76, 567
4. 2D and 3D Nonlinear MHD Simulations of Coronal Loop Heating by Alfven Waves [0]
   Poedts, S. & Goedbloed, J. P., IAU Colloquium 153: Magnetodynamic Phenomena in the Solar Atmosphere - Prototypes of Stellar Magnetic Activity (Editors: Uchida, Yutaka, Kosugi, Takeo & Hudson, Hugh S.), p. 425
5. Nonlinear magnetohydrodynamics of footpoint-driven coronal loops. [37]
   Poedts, S. & Boynton, G. C., A&A, 306, 610

1995

1. Development of operation scenarios with high bootstrap, negative shear configuration for large-aspect-ratio (LAR) bootstrap tokamak "KT-2" at KAERI [0]
   Hong, B. G., Han, J. M., Kim, S. K., Poedts, S. & De Ploey, A., Proceedings of 16th International Symposium on Fusion Engineering, 1, p. 156
2. Application of the Implicitly Updated Arnoldi Method with a Complex Shift-and-Invert Strategy in MHD [9]
   Kooper, M. N., van der Vorst, H. A., Poedts, S. & Goedbloed, J. P., Journal of Computational Physics, 118, 320

1994

1. Linear Visco-Resistive Computations of Magnetohydrodynamics Waves I. The Code and Test Cases [1]
   Erdelyi, R., Goossens, M. & Poedts, S., IAU Colloquium 144: Solar Coronal Structures (Editors: Rusin, Vojtech, Heinzel, Petr & Vial, Jean-Claude), p. 503
2. Stability of global Alfven waves (TAE, EAE) in JET tritium discharges [19]
   Kerner, W., Borba, D., Huysmans, G. T. A., Porcelli, F., Poedts, S., Goedbloed, J. P. & Betti, R., Plasma Physics and Controlled Fusion, 36, 911
3. Nonlinear wave heating of the solar corona [0]
   Poedts, S. & Goedbloed, J. P., Solar Magnetic Fields (Editors: Schüssler, Manfred & Schmidt, Wolfgang), p. 396
4. On the Quality of Resonant Absorption as a Coronal Loop Heating Mechanism [30]
   Poedts, S., Belien, A. J. C. & Goedbloed, J. P., Solar Physics, 151, 271
5. 3D nonlinear wave heating of coronal loops [3]
   Poedts, S. & Goedbloed, J. P., Space Science Reviews, 68, 103

1993

1. MHD spectroscopy: free boundary modes (ELMs) and external excitation of TAE modes [14]
   Goedbloed, J. P., Holties, H. A., Poedts, S., Huysmans, G. T. A. & Kerner, W., Plasma Physics and Controlled Fusion, 35, B277
2. MHD spectroscopy: free boundary modes (ELMs) and external excitation of TAE modes [59]
   Goedbloed, J. P., Holties, H. A., Poedts, S., Huysmans, G. T. A. & Kerner, W., Plasma Physics and Controlled Fusion, 35, B277
3. Computation of the Ideal-MHD Continuous Spectrum in Axisymmetric Plasmas [40]
   Poedts, Stefaan & Schwartz, Elisabeth, Journal of Computational Physics, 105, 165
4. Total Resonant Absorption of Acoustic Oscillations in Sunspots [26]
   Stenuit, Hilde, Poedts, Stefaan & Goossens, Marcel, Solar Physics, 147, 13

1992

1. Linear Resistive Magnetohydrodynamic Computations of Resonant Absorption of Acoustic Oscillations in Sunspots [52]
   Goossens, Marcel & Poedts, Stefaan, ApJ, 384, 348
2. Damping of global Alfven waves in tokamaks due to resonant absorption [58]
   Poedts, S., Kerner, W., Goedbloed, J. P., Keegan, B., Huysmans, G. T. A. & Schwarz, E., Plasma Physics and Controlled Fusion, 34, 1397
3. Time scales and efficiency of resonant absorption in periodically driven resistive plasmas [46]
   Poedts, Stefaan & Kerner, Wolfgang, Journal of Plasma Physics, 47, 139
4. Coronal heating: the role of resonant absorption. [1]
   Poedts, Stefaan & Goedbloed, J. P., Coronal Streamers, Coronal Loops, and Coronal and Solar Wind Composition (Editors: Mattok, C.), ESA Special Publication, 348, p. 253

1991

1. Line-Tying Effects on Stability and Heating of Solar Coronal Loops (With 2 Figures) [0]
   Halberstadt, G., Goedbloed, J. P., Poedts, S. M. & van der Linden, R. A. M., Mechanisms of Chromospheric and Coronal Heating (Editors: Ulmschneider, Peter, Priest, Eric R. & Rosner, Robert), p. 260
2. On the Time Scales and the Efficiency of Solar Coronal Loop Heating by Resonant Absorption (With 1 Figure) [1]
   Poedts, S. M., Mechanisms of Chromospheric and Coronal Heating (Editors: Ulmschneider, Peter, Priest, Eric R. & Rosner, Robert), p. 260
3. On Poloidal Mode Coupling in the Continuous Spectrum of 2d Equilibria [22]
   Poedts, Stefaan & Goossens, Marcel, Solar Physics, 133, 281
4. Ideal quasimodes reviewed in resistive magnetohydrodynamics [73]
   Poedts, Stefaan & Kerner, Wolfgang, Physical Review Letters, 66, 2871
5. Analytical study of plasma heating by resonant absorption of the modified external kink mode [4]
   van Eester, D., Goossens, M. & Poedts, S., Journal of Plasma Physics, 45, 3

1990

1. Main-Sequence Broadening in the Double Cluster H-Persei and Chi-Persei [3]
   Denoyelle, J., Waelkens, C., Cuypers, J., Degryse, K., Heynderickx, D., Lampens, P., Poedts, S., Polfliet, R., Rufener, F., Smeyers, P. & van den Abeele, K., Astrophysics and Space Science, 169, 109
2. Coronal loop heating by resonant absorption [3]
   Poedts, Stefaan, Gooseens, Marcel & Kerner, Wolfgang, Geophysical Monograph Series, 58, 257
3. Temporal evolution of resonant absorption in solar coronal loops [33]
   Poedts, Stefaan, Goossens, Marcel & Kerner, Wolfgang, Computer Physics Communications, 59, 95
4. Numerical simulation of the stationary state of periodically driven coronal loops [34]
   Poedts, Stefaan, Goossens, Marcel & Kerner, Wolfgang, Computer Physics Communications, 59, 75
5. On the Efficiency of Coronal Loop Heating by Resonant Absorption [113]
   Poedts, Stefaan, Goossens, Marcel & Kerner, Wolfgang, ApJ, 360, 279
6. Geneva photometry of stars in the double cluster H and KHI Persei. [34]
   Waelkens, C., Lampens, P., Heynderickx, D., Cuypers, J., Degryse, K., Poedts, S., Polfliet, R., Denoyelle, J., van den Abeele, K., Rufener, F. & Smeyers, P., Astronomy and Astrophysics Supplement Series, 83, 11

1989

1. Kink modes in coronal loops. [1]
   Goedbloed, J. P., Goossens, M. & Poedts, S., Plasma Astrophysics, 1, p. 103
2. Coronal heating by resonant absorption in resistive MHD. [0]
   Poedts, S., Goossens, M. & Kerner, W., Plasma Astrophysics, 1, p. 107
3. Numerical simulation of coronal heating by resonant absorption of Alfvén waves [145]
   Poedts, Stefaan, Goossens, Marcel & Kerner, Wolfgang, Solar Physics, 123, 83
4. Alfvén-wave heating in resistive MHD [54]
   Poedts, Stefaan, Kerner, Wolfgang & Goossens, Marcel, Journal of Plasma Physics, 42, 27

1988

1. The continuous spectrum of MHD waves in 2-D solar loops and arcades - Parametric study of poloidal mode coupling for poloidal magnetic fields [15]
   Poedts, S. & Goossens, M., A&A, 198, 331

1987

1. Poloidal mode coupling of Alfvén continuum modes in 2D coronal loops. [0]
   Poedts, S. & Goossens, M., The Role of Fine-Scale Magnetic Fields on the Structure of the Solar Atmosphere (Editors: Schröter, E.-H., Vázquez, M. & Wyller, A. A.), p. 277
2. Poloidal Mode Coupling of Alfvén Continuum Modes in 2D Coronal Loops [0]
   Poedts, S. & Goossens, M., The Role of Fine-Scale Magnetic Fields on the Structure of the Solar Atmosphere (Editors: Schröter, E.-H., Vázquez, M. & Wyller, A. A.), p. 272
3. The Continuous Spectrum of Magnetohydrodynamic Waves in 2d Solar Loops and Arcades - First Results on Poloidal Mode Coupling for Poloidal Magnetic Fields [18]
   Poedts, S. & Goossens, M., Solar Physics, 109, 265

1986

1. Viscous Normal Modes on Coronal Inhomogeneities and Their Role as a Heating Mechanism [23]
   Steinolfson, R. S., Priest, E. R., Poedts, S., Nocera, L. & Goossens, M., ApJ, 304, 526

1985

1. On the existence of the continuous spectrum of ideal MHD in a 2D magnetostatic equilibrium. [45]
   Goossens, M., Poedts, S. & Hermans, D., Solar Physics, 102, 51
2. The continuous spectrum of an axisymmetric self-gravitating and static equilibrium with a mixed poloidal and toroidal magnetic field [32]
   Poedts, S., Hermans, D. & Goossens, M., A&A, 151, 16

1984

1. Continuous Spectra of Oscillation Frequencies of an Axisymmetric Incompressible Equilibrium with a Poloidal Magnetic field [5]
   Goossens, M., Hermans, D. & Poedts, S., Liege International Astrophysical Colloquia, Liege International Astrophysical Colloquia, 25, p. 382
2. The Continuous Spectrum of AN Axisymmetric, Self-Gravitating Equilibrium in the Presence of a Poloidal Magnetic Field [4]
   Hermans, D., Goossens, M. & Poedts, S., Plasma Astrophysics (Editors: Guyenne, T. Duc & Hunt, James J.), ESA Special Publication, 207, p. 297
3. The continuous spectrum of an axisymmetric equilibrium with a mixed poloidal and toroidal magnetic field and with gravity included. [0]
   Poedts, S., Goossens, M. & Hermans, D., ESA Special Publication (Editors: Guyenne, T. Duc & Hunt, James J.), ESA Special Publication, 220, p. 201