Progress in 3D self-consistent full wave-PIC modelling of space resolved ECR plasma properties

Pidatella, Angelo; Galatà, Alessio; Gallo, Carmelo Sebastiano; Mauro, Giorgio; Mishra, Bharat; Naselli, Eugenia; Torrisi, Giuseppe; Mascali, David

doi:10.18429/JACoW-ECRIS2024-TUB1

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BiBTeX citation export for TUB1: Progress in 3D self-consistent full wave-PIC modelling of space resolved ECR plasma properties

@inproceedings{pidatella:ecris2024-tub1,
% --- JACoW template Dec 2024 ---
  author       = {A. Pidatella and A. Galatà and C.S. Gallo and D. Mascali and G.S. Mauro and B. Mishra and E. Naselli and G. Torrisi},
% author       = {A. Pidatella and A. Galatà and C.S. Gallo and D. Mascali and G.S. Mauro and B. Mishra and others},
% author       = {A. Pidatella and others},
  title        = {{Progress in 3D self-consistent full wave-PIC modelling of space resolved ECR plasma properties}},
  booktitle    = {Proc. 26th Int. Workshop Electron Cyclotron Resonance Ion Sources (ECRIS'24)},
  eventdate    = {2024-09-15/2024-09-19},
  pages        = {76--80},
  eid          = {TUB1},
  language     = {english},
  keywords     = {plasma, electron, ECR, simulation, ECRIS},
  venue        = {Darmstadt, Germany},
  series       = {International Workshop on Electron Cyclotron Resonance Ion Sources},
  number       = {26},
  publisher    = {JACoW Publishing},
  location     = {Geneva, Switzerland},
  date         = {2024-09},
  month        = {09},
  year         = {2024},
  issn         = {2222-5692},
  isbn         = {978-3-95450-257-8},
  doi          = {10.18429/JACoW-ECRIS2024-TUB1},
  url          = {https://jacow.org/ecris2024/papers/tub1.pdf},
  abstract     = {{We present updates of a simulation suite to model in-plasma ion-electron dynamics, including self-consistent electromagnetic (EM) wave propagation and ion population kinetics to study atomic processes in ECR plasmas. The EM absorption is modelled by a heuristic collisional term in the cold dielectric tensor. However, we are stepping beyond the cold approximation, modelling the hot tensor with non-collisional RF wave damping. The tool calculates steady-state particle distributions via a full wave-PIC code and solves for collisional-radiative process giving atomic population and charge state distribution. The scheme is general and applicable to many physics’ cases of interest for the ECRIS community, including the build-up of the charge-state-distribution and the plasma emitted X-ray and optical radiation. We present its last updates and future perspectives, using as a case-study the PANDORA scenario. We report about studying in-plasma dynamics of injected metallic species and radioisotopes ionisation efficiency for different injection conditions and plasma parameters. The code is capable of reconstructing space-resolved plasma emissivity, to be directly compared to plasma emission measurements, and modelling plasma-induced modification of radioactivity.}},
}