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publications:start [2020/01/06 14:09] – [Journal articles] jannis | publications:start [2020/09/09 20:37] – [Accepted] jannis | ||
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+ | ==== Submitted ==== | ||
- | ==== Submitted | + | ==== Under revision |
- | * **MPI-AMRVAC: | + | |
- | * **A computational study of positive streamers interacting with dielectrics**\\ X. Li, A. Sun, G. Zhang, J. Teunissen\\ Submitted to Plasma Sources Sci. Technol. | + | |
- | ==== Journal articles ==== | ||
- | * **Improvements for drift-diffusion plasma fluid models with explicit time integration**\\ J. Teunissen\\ Plasma Sources Sci. Technol. (2020) [[https:// | + | ==== Accepted ==== |
- | * **On the emergence mechanism of carrot sprites**\\ A. Malagon, J. Teunissen, H. Stenbaek-Nielsen, | + | |
+ | |||
+ | ==== Journal articles ==== | ||
+ | * **Identifying magnetic reconnection in 2D Hybrid Vlasov Maxwell simulations with Convolutional Neural Networks**\\ A. Hu, M. Sisti, F. Finelli, F. Califano, J. Dargent, M. Faganello, E. Camporeale, J. Teunissen\\ The Astrophysical Journal (ApJ) [[https:// | ||
+ | * **A Computational Study of Negative Surface Discharges: Characteristics of Surface Streamers and Surface Charges**\\ X. Li, A. Sun, J. Teunissen\\ IEEE TDEI (2020) [[https:// | ||
+ | * **The physics of streamer discharge phenomena**\\ S. Nijdam, J. Teunissen, U. Ebert\\ Plasma Sources Sci. Technol. (2020) [[https:// | ||
+ | * **MPI-AMRVAC: | ||
+ | * **A computational study of positive streamers interacting with dielectrics**\\ X. Li, A. Sun, G. Zhang, J. Teunissen\\ Plasma Sources Sci. Technol. (2020) [[https:// | ||
+ | * **Improvements for drift-diffusion plasma fluid models with explicit time integration**\\ J. Teunissen\\ Plasma Sources Sci. Technol. (2020) [[https:// | ||
+ | * **On the emergence mechanism of carrot sprites**\\ A. Malagon, J. Teunissen, H. Stenbaek-Nielsen, | ||
* **A geometric multigrid library for quadtree/ | * **A geometric multigrid library for quadtree/ | ||
* **General relativistic resistive magnetohydrodynamics with robust primitive variable recovery for accretion disk simulations**\\ B. Ripperda, F. Bacchini, O. Porth, E.R. Most, H. Olivares, A. Nathanail, L. Rezzolla, J. Teunissen, R. Keppens\\ ApJS [19 pages] (2019) [[https:// | * **General relativistic resistive magnetohydrodynamics with robust primitive variable recovery for accretion disk simulations**\\ B. Ripperda, F. Bacchini, O. Porth, E.R. Most, H. Olivares, A. Nathanail, L. Rezzolla, J. Teunissen, R. Keppens\\ ApJS [19 pages] (2019) [[https:// | ||
- | * **The effect of the stochasticity of photoionization on 3D streamer simulations**\\ B. Bagheri and J. Teunissen\\ Plasma Sources Sci. Technol. [10 pages] (2019), [[https:// | + | * **The effect of the stochasticity of photoionization on 3D streamer simulations**\\ B. Bagheri and J. Teunissen\\ Plasma Sources Sci. Technol. [10 pages] (2019), [[https:// |
* **Comparison of six simulation codes for positive streamers in air**\\ B. Bagheri, J. Teunissen, U. Ebert, M.M. Becker, S. Chen, O. Ducasse, O. Eichwald, D. Loffhagen, A. Luque, D. Mihailova, J.M. Plewa, J. van Dijk, M. Yousfi\\ Plasma Sources Sci. Technol. [20 pages] (2018), [[https:// | * **Comparison of six simulation codes for positive streamers in air**\\ B. Bagheri, J. Teunissen, U. Ebert, M.M. Becker, S. Chen, O. Ducasse, O. Eichwald, D. Loffhagen, A. Luque, D. Mihailova, J.M. Plewa, J. van Dijk, M. Yousfi\\ Plasma Sources Sci. Technol. [20 pages] (2018), [[https:// | ||
* **Afivo: a simulation framework with multigrid routines for quadtree and octree grids**\\ J. Teunissen, U. Ebert\\ Computer Physics Communications [11 pages] (2018), [[https:// | * **Afivo: a simulation framework with multigrid routines for quadtree and octree grids**\\ J. Teunissen, U. Ebert\\ Computer Physics Communications [11 pages] (2018), [[https:// | ||
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* **Electric field measurements on plasma bullets in N2 using four-wave mixing**\\ M. van der Schans, P. Böhm, J. Teunissen, S. Nijdam, W. IJzerman, U. Czarnetzki\\ Plasma Sources Sci. Technol. (2017), [[https:// | * **Electric field measurements on plasma bullets in N2 using four-wave mixing**\\ M. van der Schans, P. Böhm, J. Teunissen, S. Nijdam, W. IJzerman, U. Czarnetzki\\ Plasma Sources Sci. Technol. (2017), [[https:// | ||
* **Simulating streamer discharges in 3D with the parallel adaptive Afivo framework**\\ J. Teunissen, U. Ebert\\ J. Phys. D: Appl. Phys. (2017), [[https:// | * **Simulating streamer discharges in 3D with the parallel adaptive Afivo framework**\\ J. Teunissen, U. Ebert\\ J. Phys. D: Appl. Phys. (2017), [[https:// | ||
- | * **3D PIC-MCC simulations of discharge inception around a sharp anode in nitrogen/ | + | * **3D PIC-MCC simulations of discharge inception around a sharp anode in nitrogen/ |
- | * **The role of free electrons in the guiding of positive streamers**\\ S. Nijdam, J. Teunissen, E. Takahashi, U. Ebert\\ Plasma Sources Sci. Technol. 25, 044001 [13 pages] (2016), [[http:// | + | * **The role of free electrons in the guiding of positive streamers**\\ S. Nijdam, J. Teunissen, E. Takahashi, U. Ebert\\ Plasma Sources Sci. Technol. 25, 044001 [13 pages] (2016), [[https:// |
- | * **Comparing plasma fluid models of different order for 1D streamer ionization fronts**\\ A.H. Markosyan, J. Teunissen, S. Dujko, and U. Ebert\\ Plasma Sources Sci. Technol. 24, 065002 [13 pages] (2015), [[http:// | + | * **Comparing plasma fluid models of different order for 1D streamer ionization fronts**\\ A.H. Markosyan, J. Teunissen, S. Dujko, and U. Ebert\\ Plasma Sources Sci. Technol. 24, 065002 [13 pages] (2015), [[https:// |
- | * **Streamer discharges can move perpendicularly to the electric field**\\ S. Nijdam, E. Takahashi, J. Teunissen, U. Ebert\\ New J. Phys. 16, 103038 [9 pages] (2014), [[http:// | + | * **Streamer discharges can move perpendicularly to the electric field**\\ S. Nijdam, E. Takahashi, J. Teunissen, U. Ebert\\ New J. Phys. 16, 103038 [9 pages] (2014), [[https:// |
- | * **The inception of pulsed discharges in air: simulations in background fields above and below breakdown**\\ A.B. Sun, J. Teunissen, U. Ebert\\ J. Phys. D: Appl. Phys. 47, 445205 [9 pages] (2014), [[http:// | + | * **The inception of pulsed discharges in air: simulations in background fields above and below breakdown**\\ A.B. Sun, J. Teunissen, U. Ebert\\ J. Phys. D: Appl. Phys. 47, 445205 [9 pages] (2014), [[https:// |
- | * **Propagation of a positive streamer towards a dielectric tip in pure nitrogen and in air**\\ A. Dubinova, J. Teunissen, U. Ebert\\ IEEE Trans. Plasma Sci. 42 2392-2393 [2 pages] (2014), [[http:// | + | * **Propagation of a positive streamer towards a dielectric tip in pure nitrogen and in air**\\ A. Dubinova, J. Teunissen, U. Ebert\\ IEEE Trans. Plasma Sci. 42 2392-2393 [2 pages] (2014), [[https:// |
- | * **A time scale for electrical screening in pulsed gas discharges**\\ J. Teunissen, A.B. Sun, U. Ebert\\ J. Phys. D: Appl. Phys. 47, 365203 [7 pages] (2014), [[http:// | + | * **A time scale for electrical screening in pulsed gas discharges**\\ J. Teunissen, A.B. Sun, U. Ebert\\ J. Phys. D: Appl. Phys. 47, 365203 [7 pages] (2014), [[https:// |
- | * **3D particle simulation of positive streamer inception from a needle electrode in supercritical nitrogen**\\ A.B. Sun, J. Teunissen, U. Ebert\\ IEEE Trans. Plasma Sci. 42, 2416-2417 [2 pages] (2014), [[http:// | + | * **3D particle simulation of positive streamer inception from a needle electrode in supercritical nitrogen**\\ A.B. Sun, J. Teunissen, U. Ebert\\ IEEE Trans. Plasma Sci. 42, 2416-2417 [2 pages] (2014), [[https:// |
- | * **Controlling the weights of simulation particles: adaptive particle management using k-d trees**\\ J. Teunissen and U. Ebert\\ J. Comput. Phys. 259, 318 [13 pages] (2013), [[http:// | + | * **Controlling the weights of simulation particles: adaptive particle management using k-d trees**\\ J. Teunissen and U. Ebert\\ J. Comput. Phys. 259, 318 [13 pages] (2013), [[https:// |
- | * **Why isolated streamer discharges hardly exist above the breakdown field in atmospheric air**\\ A.B. Sun, J. Teunissen and U. Ebert\\ Geophys. Res. Lett. 40, 2417 [6 pages] (2013), [[http:// | + | * **Why isolated streamer discharges hardly exist above the breakdown field in atmospheric air**\\ A.B. Sun, J. Teunissen and U. Ebert\\ Geophys. Res. Lett. 40, 2417 [6 pages] (2013), [[https:// |
- | * **A comparison of 3D fluid, particle and hybrid model for negative streamers**\\ C. Li, J. Teunissen, M. Nool, W. Hundsdorfer, | + | * **A comparison of 3D fluid, particle and hybrid model for negative streamers**\\ C. Li, J. Teunissen, M. Nool, W. Hundsdorfer, |
==== PhD Thesis ==== | ==== PhD Thesis ==== | ||
- | * 3D Simulations and Analysis of Pulsed Discharges (2015) [[http:// | + | * 3D Simulations and Analysis of Pulsed Discharges (2015) [[https:// |