Publications of Bart van der Holst

A list of publications authored or co-authored by Bart van der Holst, 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: 0000-0001-5260-3944

List of publications ordered by citations
Number of papers: 83 (refereed: 78)
No. of citations: 4301
First author papers: 17 (refereed: 17)

2025

1. Consequences of Hot Electrons for the Structure of the Outer Heliosphere [1]
   Bair, Ethan Schuyler, Opher, Merav, Kornbleuth, Marc Zachary, Zieger, Bertalan, Toth, Gabor & van der Holst, Bart, ApJ, 988, 223
2. Evidence of Time-dependent Diffusive Shock Acceleration in the 2022 September 5 Solar Energetic Particle Event [5]
   Chen, Xiaohang, Zhao, Lulu, Giacalone, Joe, Sachdeva, Nishtha, Sokolov, Igor V., Tóth, Gábor, Cohen, Christina M. S., Lario, David, Guo, Fan, Kouloumvakos, Athanasios, Gombosi, Tamas I., Huang, Zhenguang, Manchester, Ward B., IV, van der Holst, Bart, Liu, Weihao, McComas, David J., Hill, Matthew E. & Ho, George C., ApJ, 994, 242
3. Validation of Long-term Solar Coronal Modeling Using FORWARD [1]
   Koban, Gergely, Szente, Judit, van der Holst, Bart, Toth, Gabor & Landi, Enrico, ApJS, 280, 51
4. High-resolution Simulation of Coronal Mass Ejection–Corotating Interaction Region Interactions: Mesoscale Solar Wind Structure Formation Observable by the SWIFT Constellation [0]
   Manchester, W. B., IV, Sachdeva, Nishtha, Kilpua, Emilia, Ala-Lahti, Matti, Soni, Shirsh Lata, Huang, Zhenguang, Chen, Hongfan, Jivani, Aniket, van der Holst, Bart, Szabo, Adam & Akhavan-Tafti, Mojtaba, ApJ, 992, 51
5. Modeling the Energy Release in Solar Eruptive Events [0]
   van der Holst, Bart, Antiochos, Spiro K., Sachdeva, Nishtha, Toth, Gabor, Dahlin, Joel T. & Gombosi, Tamas I., ApJ, 995, 221

2024

1. Decent Estimate of CME Arrival time from a Data-assimilated Ensemble in the Alfvén Wave Solar atmosphere Model (DECADE-AWSoM) [0]
   Chen, Hongfan, Sachdeva, Nishtha, Huang, Zhenguang, Holst, Bartholomeus van der, , Ward Beecher Manchester, IV, Jivani, Aniket, Zou, Shasha, Chen, Yang, Huan, Xun & Toth, Gabor, essoar.172745166
2. Numerical Modeling of Energetic Charged-particle Transport with SPECTRUM Software: General Approach and Artificial Effects due to Field Discretization [3]
   Guzmán, J. G. Alonso, Florinski, V., Tóth, G., Sharma, S., van der Holst, B. & Opher, M., ApJS, 272, 46
3. Adjusting the Potential Field Source Surface Height Based on Magnetohydrodynamic Simulations [9]
   Huang, Zhenguang, Tóth, Gábor, Huang, Jia, Sachdeva, Nishtha, van der Holst, Bart & Manchester, Ward B., ApJ, 965, L1
4. Solar Wind Driven from GONG Magnetograms in the Last Solar Cycle [13]
   Huang, Zhenguang, Tóth, Gábor, Sachdeva, Nishtha & van der Holst, Bart, ApJ, 965, 1
5. Analytic Model and Magnetohydrodynamic Simulations of Three-dimensional Magnetic Switchbacks [11]
   Shi, Chen, Velli, Marco, Toth, Gabor, Zhang, Kun, Tenerani, Anna, Huang, Zesen, Sioulas, Nikos & van der Holst, Bart, ApJ, 964, L28
6. AWSoM Magnetohydrodynamic Simulation of a Solar Active Region. II. Statistical Analysis of Alfvén Wave Dissipation and Reflection, Scaling Laws, and Energy Budget on Coronal Loops [8]
   Shi, Tong, Manchester, Ward, Landi, Enrico, van der Holst, Bart, Szente, Judit, Chen, Yuxi, Tóth, Gábor, Bertello, Luca & Pevtsov, Alexander, ApJ, 961, 60
7. Simulating Compressive Stream Interaction Regions during Parker Solar Probe's First Perihelion Using Stream-aligned Magnetohydrodynamics [5]
   Wraback, E. M., Hoffmann, A. P., Manchester, W. B., Sokolov, I. V., van der Holst, B. & Carpenter, D., ApJ, 962, 182

2023

1. Parker Solar Probe Observations of High Plasma β Solar Wind from the Streamer Belt [14]
   Huang, Jia, Kasper, J. C., Larson, Davin E., McManus, Michael D., Whittlesey, P., Livi, Roberto, Rahmati, Ali, Romeo, Orlando, Klein, K. G., Sun, Weijie, van der Holst, Bart, Huang, Zhenguang, Jian, Lan K., Szabo, Adam, Verniero, J. L., Chen, C. H. K., Lavraud, B., Liu, Mingzhe, Badman, Samuel T., Niembro, Tatiana, Paulson, Kristoff, Stevens, M., Case, A. W., Pulupa, Marc, Bale, Stuart D. & Halekas, J. S., ApJS, 265, 47
2. Modeling the Solar Wind during Different Phases of the Last Solar Cycle [23]
   Huang, Zhenguang, Tóth, Gábor, Sachdeva, Nishtha, Zhao, Lulu, van der Holst, Bart, Sokolov, Igor, Manchester, Ward B. & Gombosi, Tamas I., ApJ, 946, L47
3. Solar Wind Modeling with the Alfvén Wave Solar atmosphere Model Driven by HMI-based Near-real-time Maps by the National Solar Observatory [14]
   Sachdeva, Nishtha, Manchester, Ward B., IV, Sokolov, Igor, Huang, Zhenguang, Pevtsov, Alexander, Bertello, Luca, Pevtsov, Alexei A., Toth, Gabor, van der Holst, Bart & Henney, Carl J., ApJ, 952, 117
4. Nonequilibrium Ionization Effects on Synthetic Spectra in the AWSoM Solar Corona [7]
   Szente, J., Landi, E. & van der Holst, B., ApJS, 269, 37
5. Theory of Magnetic Switchbacks Fully Supported by Parker Solar Probe Observations [15]
   Toth, Gabor, Velli, Marco & van der Holst, Bart, ApJ, 957, 95
6. Can One Predict Coronal Mass Ejection Arrival Times with Thirty-Minute Accuracy? [0]
   Toth, Gabor, van der Holst, Bartholomeus & Beecher, Ward Manchester, IV, essoar.167751578
7. Investigating a Solar Wind Stream Interaction Region using Interplanetary Spacecraft Radio Signals: A Magnetohydrodynamic Simulation Study [3]
   Wexler, David B., Manchester, Ward B., Jian, Lan K., Wilson, Lynn B., Gopalswamy, Natchimuthuk, Song, Paul, Kooi, Jason E., van der Holst, Bart & Jensen, Elizabeth A., ApJ, 955, 90
8. Solar Wind with Field Lines and Energetic Particles (SOFIE) Model: Application to Historical Solar Energetic Particle Events [0]
   Zhao, Lulu, Sokolov, Igor V., Gombosi, Tamas I., Lario, David, Whitman, Kathryn, Huang, Zhenguang, Toth, Gabor, Beecher Manchester, Ward, IV, van der Holst, Bartholomeus & Sachdeva, Nishtha, 169603574.40060640

2022

1. Modeling the Solar Wind During Different Phases of the Last Solar Cycle [1]
   Huang, Zhenguang, Toth, Gabor, Sachdeva, Nishtha, Zhao, Lulu, van der Holst, Bart, Sokolov, Igor, Manchester, Ward & Gombosi, Tamas, essoar.10512539
2. Global Sensitivity Analysis and Uncertainty Quantification for Background Solar Wind using the Alfvén Wave Solar Atmosphere Model [0]
   Jivani, Aniket, Sachdeva, Nishtha, Huang, Zhenguang, Chen, Yang, van der Holst, Bart, Manchester, Ward, Iong, Daniel, Chen, Hongfan, Zou, Shasha, Huan, Xun & Toth, Gabor, essoar.10512216
3. AWSoM Magnetohydrodynamic Simulation of a Solar Active Region with Realistic Spectral Synthesis [15]
   Shi, Tong, Manchester, Ward, IV, Landi, Enrico, van der Holst, Bart, Szente, Judit, Chen, Yuxi, Tóth, Gábor, Bertello, Luca & Pevtsov, Alexander, ApJ, 928, 34
4. Charge State Calculation for Global Solar Wind Modeling [26]
   Szente, J., Landi, E. & van der Holst, B., ApJ, 926, 35
5. Improving the Alfvén Wave Solar Atmosphere Model Based on Parker Solar Probe Data [39]
   van der Holst, B., Huang, J., Sachdeva, N., Kasper, J. C., Manchester, W. B., IV, Borovikov, D., Chandran, B. D. G., Case, A. W., Korreck, K. E., Larson, D., Livi, R., Stevens, M., Whittlesey, P., Bale, S. D., Pulupa, M., Malaspina, D. M., Bonnell, J. W., Harvey, P. R., Goetz, K. & MacDowall, R. J., ApJ, 925, 146

2021

1. One Year in the Life of Young Suns: Data-constrained Corona-wind Model of κ¹ Ceti [26]
   Airapetian, Vladimir S., Jin, Meng, Lüftinger, Theresa, Boro Saikia, Sudeshna, Kochukhov, Oleg, Güdel, Manuel, Van Der Holst, Bart & Manchester, W., IV, ApJ, 916, 96
2. What sustained multi-disciplinary research can achieve: The space weather modeling framework [92]
   Gombosi, Tamas I., Chen, Yuxi, Glocer, Alex, Huang, Zhenguang, Jia, Xianzhe, Liemohn, Michael W., Manchester, Ward B., Pulkkinen, Tuija, Sachdeva, Nishtha, Al Shidi, Qusai, Sokolov, Igor V., Szente, Judit, Tenishev, Valeriy, Toth, Gabor, van der Holst, Bart, Welling, Daniel T., Zhao, Lulu & Zou, Shasha, Journal of Space Weather and Space Climate, 11, 42
3. Simulating Solar Maximum Conditions Using the Alfvén Wave Solar Atmosphere Model (AWSoM) [35]
   Sachdeva, Nishtha, Tóth, Gábor, Manchester, Ward B., van der Holst, Bart, Huang, Zhenguang, Sokolov, Igor V., Zhao, Lulu, Shidi, Qusai Al, Chen, Yuxi, Gombosi, Tamas I., Henney, Carl J., Lloveras, Diego G. & Vásquez, Alberto M., ApJ, 923, 176
4. Threaded-field-line Model for the Low Solar Corona Powered by the Alfvén Wave Turbulence [43]
   Sokolov, Igor V., Holst, Bart van der, Manchester, Ward B., Su Ozturk, Doga Can, Szente, Judit, Taktakishvili, Aleksandre, Tóth, Gábor, Jin, Meng & Gombosi, Tamas I., ApJ, 908, 172

2020

1. Thermodynamic Structure of the Solar Corona: Tomographic Reconstructions and MHD Modeling [12]
   Lloveras, Diego G., Vásquez, Alberto M., Nuevo, Federico A., Mac Cormack, Cecilia, Sachdeva, Nishtha, Manchester, Ward, Van der Holst, Bartholomeus & Frazin, Richard A., Solar Physics, 295, 76

2019

1. Validation of the Alfvén Wave Solar Atmosphere Model (AWSoM) with Observations from the Low Corona to 1 au [78]
   Sachdeva, Nishtha, van der Holst, Bart, Manchester, Ward B., Tóth, Gabor, Chen, Yuxi, Lloveras, Diego G., Vásquez, Alberto M., Lamy, Philippe, Wojak, Julien, Jackson, Bernard V., Yu, Hsiu-Shan & Henney, Carl J., ApJ, 887, 83
2. SPECTRUM: Synthetic Spectral Calculations for Global Space Plasma Modeling [14]
   Szente, J., Landi, E., Manchester, W. B., IV, Toth, G., van der Holst, B. & Gombosi, T. I., ApJS, 242, 1
3. Predictions for the First Parker Solar Probe Encounter [45]
   van der Holst, B., Manchester, W. B., IV, Klein, K. G. & Kasper, J. C., ApJ, 872, L18

2017

1. Chromosphere to 1 AU Simulation of the 2011 March 7th Event: A Comprehensive Study of Coronal Mass Ejection Propagation [93]
   Jin, M., Manchester, W. B., van der Holst, B., Sokolov, I., Tóth, G., Vourlidas, A., de Koning, C. A. & Gombosi, T. I., ApJ, 834, 172

2014

1. Alfvén Wave Solar Model (AWSoM): Coronal Heating [492]
   van der Holst, B., Sokolov, I. V., Meng, X., Jin, M., Manchester, W. B., IV, Tóth, G. & Gombosi, T. I., ApJ, 782, 81

2013

1. Numerical Simulations of Coronal Mass Ejection on 2011 March 7: One-temperature and Two-temperature Model Comparison [56]
   Jin, M., Manchester, W. B., van der Holst, B., Oran, R., Sokolov, I., Toth, G., Liu, Y., Sun, X. D. & Gombosi, T. I., ApJ, 773, 50
2. Magnetohydrodynamic Waves and Coronal Heating: Unifying Empirical and MHD Turbulence Models [188]
   Sokolov, Igor V., van der Holst, Bart, Oran, Rona, Downs, Cooper, Roussev, Ilia I., Jin, Meng, Manchester, Ward B., IV, Evans, Rebekah M. & Gombosi, Tamas I., ApJ, 764, 23
3. Simulating radiative shocks with the CRASH laser package [13]
   van der Holst, B., Tóth, G., Sokolov, I. V., Torralva, B. R., Powell, K. G., Drake, R. P., Klapisch, M., Busquet, M., Fryxell, B. & Myra, E. S., High Energy Density Physics, 9, 8

2012

1. Understanding SDO/AIA Observations of the 2010 June 13 EUV Wave Event: Direct Insight from a Global Thermodynamic MHD Simulation [101]
   Downs, Cooper, Roussev, Ilia I., van der Holst, Bart, Lugaz, Noé & Sokolov, Igor V., ApJ, 750, 134
2. Coronal Heating by Surface Alfvén Wave Damping: Implementation in a Global Magnetohydrodynamics Model of the Solar Wind [45]
   Evans, R. M., Opher, M., Oran, R., van der Holst, B., Sokolov, I. V., Frazin, R., Gombosi, T. I. & Vásquez, A., ApJ, 756, 155
3. Dynamic Coupling of Convective Flows and Magnetic Field during Flux Emergence [39]
   Fang, Fang, Manchester, Ward, IV, Abbett, William P. & van der Holst, Bart, ApJ, 745, 37
4. Buildup of Magnetic Shear and Free Energy during Flux Emergence and Cancellation [38]
   Fang, Fang, Manchester, Ward, IV, Abbett, William P. & van der Holst, Bart, ApJ, 754, 15
5. A Global Two-temperature Corona and Inner Heliosphere Model: A Comprehensive Validation Study [63]
   Jin, M., Manchester, W. B., van der Holst, B., Gruesbeck, J. R., Frazin, R. A., Landi, E., Vasquez, A. M., Lamy, P. L., Llebaria, A., Fedorov, A., Toth, G. & Gombosi, T. I., ApJ, 745, 6
6. Parallel, grid-adaptive approaches for relativistic hydro and magnetohydrodynamics [276]
   Keppens, R., Meliani, Z., van Marle, A. J., Delmont, P., Vlasis, A. & van der Holst, B., Journal of Computational Physics, 231, 718
7. The Coupled Evolution of Electrons and Ions in Coronal Mass Ejection-driven shocks [49]
   Manchester, W. B., IV, van der Holst, B., Tóth, G. & Gombosi, T. I., ApJ, 756, 81
8. Adaptive numerical algorithms in space weather modeling [662]
   Tóth, Gábor, van der Holst, Bart, Sokolov, Igor V., De Zeeuw, Darren L., Gombosi, Tamas I., Fang, Fang, Manchester, Ward B., Meng, Xing, Najib, Dalal, Powell, Kenneth G., Stout, Quentin F., Glocer, Alex, Ma, Ying-Juan & Opher, Merav, Journal of Computational Physics, 231, 870
9. Simulating radiative shocks in nozzle shock tubes [12]
   van der Holst, B., Tóth, G., Sokolov, I. V., Daldorff, L. K. S., Powell, K. G. & Drake, R. P., High Energy Density Physics, 8, 161

2011

1. Studying Extreme Ultraviolet Wave Transients with a Digital Laboratory: Direct Comparison of Extreme Ultraviolet Wave Observations to Global Magnetohydrodynamic Simulations [92]
   Downs, Cooper, Roussev, Ilia I., van der Holst, Bart, Lugaz, Noé, Sokolov, Igor V. & Gombosi, Tamas I., ApJ, 728, 2
2. Radiative effects in radiative shocks in shock tubes [34]
   Drake, R. P., Doss, F. W., McClarren, R. G., Adams, M. L., Amato, N., Bingham, D., Chou, C. C., DiStefano, C., Fidkowski, K., Fryxell, B., Gombosi, T. I., Grosskopf, M. J., Holloway, J. P., van der Holst, B., Huntington, C. M., Karni, S., Krauland, C. M., Kuranz, C. C., Larsen, E., van Leer, B., Mallick, B., Marion, D., Martin, W., Morel, J. E., Myra, E. S., Nair, V., Powell, K. G., Rauchwerger, L., Roe, P., Rutter, E., Sokolov, I. V., Stout, Q., Torralva, B. R., Toth, G., Thornton, K. & Visco, A. J., High Energy Density Physics, 7, 130
3. Obtaining Potential Field Solutions with Spherical Harmonics and Finite Differences [111]
   Tóth, Gábor, van der Holst, Bart & Huang, Zhenguang, ApJ, 732, 102
4. CRASH: A Block-adaptive-mesh Code for Radiative Shock Hydrodynamics—Implementation and Verification [98]
   van der Holst, B., Tóth, G., Sokolov, I. V., Powell, K. G., Holloway, J. P., Myra, E. S., Stout, Q., Adams, M. L., Morel, J. E., Karni, S., Fryxell, B. & Drake, R. P., ApJS, 194, 23

2010

1. Toward a Realistic Thermodynamic Magnetohydrodynamic Model of the Global Solar Corona [94]
   Downs, Cooper, Roussev, Ilia I., van der Holst, Bart, Lugaz, Noé, Sokolov, Igor V. & Gombosi, Tamas I., ApJ, 712, 1219
2. Simulation of Flux Emergence from the Convection Zone to the Corona [56]
   Fang, Fang, Manchester, Ward, Abbett, William P. & van der Holst, Bart, ApJ, 714, 1649
3. A Data-driven, Two-temperature Solar Wind Model with Alfvén Waves [152]
   van der Holst, B., Manchester, W. B., IV, Frazin, R. A., Vásquez, A. M., Tóth, G. & Gombosi, T. I., ApJ, 725, 1373

2009

1. An exact Riemann-solver-based solution for regular shock refraction [10]
   Delmont, P., Keppens, R. & van der Holst, B., Journal of Fluid Mechanics, 627, 33
2. Jet Stability: A Computational Survey [4]
   Keppens, Rony, Meliani, Zakaria, Baty, Hubert & van der Holst, Bart, Jets From Young Stars V (Editors: Gracia, José, de Colle, Fabio & Downes, Turlough), p.179
3. 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
4. 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
5. Breakout Coronal Mass Ejection or Streamer Blowout: The Bugle Effect [46]
   van der Holst, B., Manchester, W., IV, Sokolov, I. V., Tóth, G., Gombosi, T. I., DeZeeuw, D. & Cohen, O., ApJ, 693, 1178

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. Extragalactic jets with helical magnetic fields: relativistic MHD simulations [50]
   Keppens, R., Meliani, Z., van der Holst, B. & Casse, F., A&A, 486, 663
3. A multidimensional grid-adaptive relativistic magnetofluid code [53]
   van der Holst, B., Keppens, R. & Meliani, Z., Computer Physics Communications, 179, 617

2007

1. PHOENIX: MHD spectral code for rotating laboratory and gravitating astrophysical plasmas [28]
   Blokland, J. W. S., van der Holst, B., Keppens, R. & Goedbloed, J. P., Journal of Computational Physics, 226, 509
2. Comparison between 2.5D and 3D simulations of coronal mass ejections [24]
   Jacobs, C., van der Holst, B. & Poedts, S., A&A, 470, 359
3. Hybrid block-AMR in cartesian and curvilinear coordinates: MHD applications [80]
   van der Holst, B. & Keppens, R., Journal of Computational Physics, 226, 925
4. 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. 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
2. The initiation of coronal mass ejections by magnetic flux emergence [18]
   Dubey, G., van der Holst, B. & Poedts, S., A&A, 459, 927
3. Initiation of CMEs by Magnetic Flux Emergence [6]
   Dubey, Govind, van der Holst, Bart & Poedts, Stefaan, Journal of Astrophysics and Astronomy, 27, 159
4. 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

2005

1. 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
2. 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
3. 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. No additional flow continua in magnetohydrodynamics [16]
   Goedbloed, J. P., Beliën, A. J. C., Holst, B. van der & Keppens, R., Physics of Plasmas, 11, 4332
2. Unstable continuous spectra of transonic axisymmetric plasmas [46]
   Goedbloed, J. P., Beliën, A. J. C., van der Holst, B. & Keppens, R., Physics of Plasmas, 11, 28

2003

1. Jeans instability of an inhomogeneous streaming dusty plasma [12]
   Pandey, B. P., van Dere Holst, B., Vranjes, J. & Poedts, S., Pramana, 61, 109

2002

1. New numerical tools to study waves and instabilities of flowing plasmas [1]
   Belien, A. J. C., Botchev, M. A., Goedbloed, J. P., van der Holst, B. & Keppens, R., Computer Physics Communications, 147, 497
2. FINESSE: Axisymmetric MHD Equilibria with Flow [71]
   Beliën, A. J. C., Botchev, M. A., Goedbloed, J. P., van der Holst, B. & Keppens, R., Journal of Computational Physics, 182, 91

2000

1. New Alfvén Continuum Gaps and Global Modes Induced by Toroidal Flow [44]
   van der Holst, B., Beliën, A. J. C. & Goedbloed, J. P., Physical Review Letters, 84, 2865
2. Low frequency Alfvén waves induced by toroidal flows [64]
   van der Holst, B., Beliën, A. J. C. & Goedbloed, J. P., Physics of Plasmas, 7, 4208

1999

1. Calculation of resistive magnetohydrodynamic spectra in tokamaks [10]
   van der Holst, B., Beliën, A. J. C., Goedbloed, J. P., Nool, M. & van der Ploeg, A., Physics of Plasmas, 6, 1554
2. Magnetohydrodynamic spectrum of gravitating plane plasmas with flow [9]
   van der Holst, B., Nijboer, R. J. & Goedbloed, J. P., Journal of Plasma Physics, 61, 221

1997

1. Calculating magnetohydrodynamic flow spectra [18]
   Nijboer, R. J., Holst, B. v. d., Poedts, S. & Goedbloed, J. P., Computer Physics Communications, 106, 39