Publications of Andrea Lani

A list of publications authored or co-authored by Andrea Lani, 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: 0000-0003-4017-215X

List of publications ordered by citations
Number of papers: 44 (refereed: 42)
No. of citations: 689
First author papers: 3 (refereed: 3)

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. 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
  3. 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
  4. 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. 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
  2. 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
  3. 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
  4. Experimental investigation on MHD flow manipulation in high enthalpy air plasma [2]
    Oswald, Johannes W., Lani, Andrea & Herdrich, Georg, Vacuum, 240, 114565
  5. 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
  6. 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
  7. 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
  8. 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
  9. 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

2024

  1. 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
  2. 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
  3. 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
  4. Influence of magnetohydrodynamics configuration on aerothermodynamics during Martian reentry [8]
    Sharma, Vatsalya, Giangaspero, Vincent F., Poedts, Stefaan & Lani, Andrea, Physics of Fluids, 36, 036103

2023

  1. 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
  2. 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
  3. 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
  4. Effect of electron number densities on the radio signal propagation in an inductively coupled plasma facility [13]
    Luís, Diana, Giangaspero, Vincent, Viladegut, Alan, Lani, Andrea, Camps, Adriano & Chazot, Olivier, Acta Astronautica, 212, 408
  5. Assessment of MHD-relevant parameters in high enthalpy air plasma for flow manipulation experiments [5]
    Oswald, Johannes W., Behnke, Alexander, Herdrich, Georg, Schlachter, Sonja I., Dalban-Canassy, Matthieu & Lani, Andrea, Vacuum, 217, 112504
  6. 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

2022

  1. 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
  2. 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
  3. 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
  4. Development of an implicit high-order flux reconstruction solver for the Langtry-Menter Laminar-Turbulent Transition RANS model [2]
    Vandenhoeck, Ray, Lani, Andrea & Steelant, Johan, Computer Physics Communications, 278, 108408

2021

  1. r-adaptive algorithms for high-speed flows and plasma simulations [5]
    Ben Ameur, Firas & Lani, Andrea, Computer Physics Communications, 261, 107700
  2. 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. Blackout analysis of Mars entry missions [12]
    Ramjatan, Sahadeo, Lani, A., Boccelli, S., Van Hove, B., Karatekin, Ö., Magin, T. & Thoemel, J., Journal of Fluid Mechanics, 904, A26

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. An entropy-variables-based formulation of residual distribution schemes for non-equilibrium flows [5]
    Garicano-Mena, Jesús, Lani, Andrea & Degrez, Gérard, Journal of Computational Physics, 362, 163

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. An object-oriented implementation of a parallel Monte Carlo code for radiation transport [16]
    Santos, Pedro Duarte & Lani, Andrea, Computer Physics Communications, 202, 233
  3. Analysis of non-equilibrium phenomena in inductively coupled plasma generators [21]
    Zhang, W., Lani, A. & Panesi, M., Physics of Plasmas, 23, 073512

2015

  1. Assessment of Heat Flux Prediction Capabilities of Residual Distribution Method: Application to Atmospheric Entry Problems [4]
    Mena, Jesús Garicano, Pepe, Raffaele, Lani, Andrea & Deconinck, Herman, Communications in Computational Physics, 17, 682

2014

  1. 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

2013

  1. Variable High-Order Multiblock Overlapping Grid Methods for Mixed Steady and Unsteady Multiscale Viscous Flows, Part II: Hypersonic Nonequilibrium Flows [3]
    Lani, Andrea, Sjögreen, Björn, Yee, H. C. & Henshaw, William D., Communications in Computational Physics, 13, 583
  2. Conservative Residual Distribution Method for Viscous Double Cone Flows in Thermochemical Nonequilibrium [7]
    Lani, Andrea, Panesi, Marco & Deconinck, Herman, Communications in Computational Physics, 13, 479
  3. Modeling of non-equilibrium phenomena in expanding flows by means of a collisional-radiative model [31]
    Munafò, A., Lani, A., Bultel, A. & Panesi, M., Physics of Plasmas, 20, 073501
  4. Collisional radiative coarse-grain model for ionization in air [52]
    Panesi, Marco & Lani, Andrea, Physics of Fluids, 25, 057101-057101-27

2012

  1. Assessment of CFD capability for prediction of hypersonic shock interactions [73]
    Knight, Doyle, Longo, José, Drikakis, Dimitris, Gaitonde, Datta, Lani, Andrea, Nompelis, Ioannis, Reimann, Bodo & Walpot, Louis, Progress in Aerospace Sciences, 48, 8

2011

  1. A finite volume implicit time integration method for solving the equations of ideal magnetohydrodynamics for the hyperbolic divergence cleaning approach [38]
    Yalim, M. S., Vanden Abeele, D., Lani, A., Quintino, T. & Deconinck, H., Journal of Computational Physics, 230, 6136

2009

  1. REVIEW ARTICLE: Modelling of high-enthalpy, high-Mach number flows [17]
    Degrez, G., Lani, A., Panesi, M., Chazot, O. & Deconinck, H., Journal of Physics D Applied Physics, 42, 194004

Created on Fri May 8 04:34:04 2026.