- 2308.01276v1
3.14 MB, PDF document

Research output: Working paper › Preprint

Published

Arxiv, 2023.

Research output: Working paper › Preprint

Warwick, A & Gratus, J 2023 'Moment tracking and their coordinate transformations for macroparticles with an application to plasmas around black holes' Arxiv.

Warwick, A., & Gratus, J. (2023). *Moment tracking and their coordinate transformations for macroparticles with an application to plasmas around black holes*. Arxiv.

Warwick A, Gratus J. Moment tracking and their coordinate transformations for macroparticles with an application to plasmas around black holes. Arxiv. 2023 Aug 2.

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title = "Moment tracking and their coordinate transformations for macroparticles with an application to plasmas around black holes",

abstract = "Particle-in-cell codes usually represent large groups of particles as a single macroparticle. These codes are computationally efficient but lose information about the internal structure of the macroparticle. To improve the accuracy of these codes, this work presents a method in which, as well as tracking the macroparticle, the moments of the macroparticle are also tracked. Although the equations needed to track these moments are known, the coordinate transformations for moments where the space and time coordinates are mixed cannot be calculated using the standard method for representing moments. These coordinate transformations are important in astrophysical plasma, where there is no preferred coordinate system. This work uses the language of Schwartz distributions to calculate the coordinate transformations of moments. Both the moment tracking and coordinate transformation equations are tested by modelling the motion of uncharged particles in a circular orbit around a black hole in both Schwarzschild and Kruskal-Szekeres coordinates. Numerical testing shows that the error in tracking moments is small, and scales quadratically. This error can be improved by including higher order moments. By choosing an appropriate method for using these moments to deposit the charge back onto the grid, a full particle-in-cell code can be developed.",

keywords = "coordinate transformations, Particle-in-cell plasma simulations, Accelerator physics",

author = "Alex Warwick and Jonathan Gratus",

note = "25 pages, 8 figures, 2 tables",

year = "2023",

month = aug,

day = "2",

language = "Undefined/Unknown",

publisher = "Arxiv",

type = "WorkingPaper",

institution = "Arxiv",

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TY - UNPB

T1 - Moment tracking and their coordinate transformations for macroparticles with an application to plasmas around black holes

AU - Warwick, Alex

AU - Gratus, Jonathan

N1 - 25 pages, 8 figures, 2 tables

PY - 2023/8/2

Y1 - 2023/8/2

N2 - Particle-in-cell codes usually represent large groups of particles as a single macroparticle. These codes are computationally efficient but lose information about the internal structure of the macroparticle. To improve the accuracy of these codes, this work presents a method in which, as well as tracking the macroparticle, the moments of the macroparticle are also tracked. Although the equations needed to track these moments are known, the coordinate transformations for moments where the space and time coordinates are mixed cannot be calculated using the standard method for representing moments. These coordinate transformations are important in astrophysical plasma, where there is no preferred coordinate system. This work uses the language of Schwartz distributions to calculate the coordinate transformations of moments. Both the moment tracking and coordinate transformation equations are tested by modelling the motion of uncharged particles in a circular orbit around a black hole in both Schwarzschild and Kruskal-Szekeres coordinates. Numerical testing shows that the error in tracking moments is small, and scales quadratically. This error can be improved by including higher order moments. By choosing an appropriate method for using these moments to deposit the charge back onto the grid, a full particle-in-cell code can be developed.

AB - Particle-in-cell codes usually represent large groups of particles as a single macroparticle. These codes are computationally efficient but lose information about the internal structure of the macroparticle. To improve the accuracy of these codes, this work presents a method in which, as well as tracking the macroparticle, the moments of the macroparticle are also tracked. Although the equations needed to track these moments are known, the coordinate transformations for moments where the space and time coordinates are mixed cannot be calculated using the standard method for representing moments. These coordinate transformations are important in astrophysical plasma, where there is no preferred coordinate system. This work uses the language of Schwartz distributions to calculate the coordinate transformations of moments. Both the moment tracking and coordinate transformation equations are tested by modelling the motion of uncharged particles in a circular orbit around a black hole in both Schwarzschild and Kruskal-Szekeres coordinates. Numerical testing shows that the error in tracking moments is small, and scales quadratically. This error can be improved by including higher order moments. By choosing an appropriate method for using these moments to deposit the charge back onto the grid, a full particle-in-cell code can be developed.

KW - coordinate transformations

KW - Particle-in-cell plasma simulations

KW - Accelerator physics

M3 - Preprint

BT - Moment tracking and their coordinate transformations for macroparticles with an application to plasmas around black holes

PB - Arxiv

ER -