Local, Explicit, and Charge-Conserving Electromagnetic Particle-In-Cell Algorithm on Unstructured Grids

Na, Dong-Yeop; Moon, Haksu; Omelchenko, Y. A.; Teixeira, F.L.

doi:10.1109/tps.2016.2582143

Cited by 39 publications

(28 citation statements)

References 66 publications

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“…14. The proposed FETD-BOR solver is incorporated into a PIC algorithm [66,67,68] to simulate the wave-plasma interaction in the device [9]. The PIC algorithm is based on an unstructured grid and explained in detail in [9,24,25]. For this problem it suffices to consider the TE φ polarized field with m = 0.…”

Section: Backward-wave Oscillator (Bwo) In the Relativistic Regimementioning

confidence: 99%

“…It is highly desirable to develop BOR FE solvers in the time domain as well. Timedomain FE solvers are better suited for simulating broadband problems, for capturing transient processes such as those involved in beam-wave interactions [23,24,25], and for handling non-linear problems. However, the use of the second-order vector wave equation as a starting point for a time-domain FE formulation, as done in frequency-domain Maxwell FE solvers, is inadequate.…”

Section: Introductionmentioning

confidence: 99%

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Finite element time-domain body-of-revolution Maxwell solver based on discrete exterior calculus

Borges

Teixeira

2019

Journal of Computational Physics

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We present a finite-element time-domain (FETD) Maxwell solver for the analysis of body-of-revolution (BOR) geometries based on discrete exterior calculus (DEC) of differential forms and transformation optics (TO) concepts. We explore TO principles to map the original 3-D BOR problem to a 2-D one in the meridian ρz-plane based on a Cartesian coordinate system where the cylindrical metric is fully embedded into the constitutive properties of an effective inhomogeneous and anisotropic medium that fills the domain. The proposed solver uses a (TE φ , TM φ ) field decomposition and an appropriate set of DEC-based basis functions on an irregular grid discretizing the meridian plane. A symplectic time discretization based on a leap-frog scheme is applied to obtain the full-discrete marching-on-time algorithm. We validate the algorithm by comparing the numerical results against analytical solutions for resonant fields in cylindrical cavities and against pseudo-analytical solutions for fields radiated by cylindrically symmetric antennas in layered media. We also illustrate the application of the algorithm for a particlein-cell (PIC) simulation of beam-wave interactions inside a high-power backward-wave oscillator.

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Section: Backward-wave Oscillator (Bwo) In the Relativistic Regimementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Finite element time-domain body-of-revolution Maxwell solver based on discrete exterior calculus

Borges

Teixeira

2019

Journal of Computational Physics

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“…Therefore, all electromagnetic phenomena can be predicted and explained with this discrete electromagnetic theory with a appropriate discretization length scale. Besides, due to the charge conservation property, as will be shown, the numerical simulation of Maxwell's equations with DEC will not lead to spurious solutions [3,17].…”

Section: Introductionmentioning

confidence: 82%

Electromagnetic Theory With Discrete Exterior Calculus

Chen¹,

Chew²

2017

PIER

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Abstract-A self-contained electromagnetic theory is developed on a simplicial lattice. Instead of dealing with vectorial field, discrete exterior calculus (DEC) studies the discrete differential forms of electric and magnetic fields, and circumcenter dual is adopted to achieve diagonal Hodge star operators. In this paper, Gauss' theorem and Stokes' theorem are shown to be satisfied inherently within DEC. Many other electromagnetic theorems, such as Huygens' principle, reciprocity theorem, and Poynting's theorem, can also be derived on this simplicial lattice consistently with an appropriate definition of wedge product between cochains. The preservation of these theorems guarantees that this treatment of Maxwell's equations will not lead to spurious solutions.

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“…The fundamentals of present finite element time-domain (FETD) Maxwell field solver are briefly summarized in this appendix. A more comprehensive discussion of the Maxwell field solver, together with various details on the scatter, gather, and pusher steps of the EM-PIC algorithm can be found in [16,17,18].…”

Section: Appendix a Fetd Maxwell Field Solvermentioning

confidence: 99%

“…Thus, the linear solve in (A.6) can be performed very quickly. Nevertheless, since the linear solve is needed at every step n of the time evolution, a sparse approximate inverse (SPAI) of [ ] may be computed priori to the start of the time-update to obviate the need for the linear solve [30,17].…”

Section: Appendix a Fetd Maxwell Field Solvermentioning

confidence: 99%

Diagnosing numerical Cherenkov instabilities in relativistic plasma simulations based on general meshes

Nicolini

Lee

et al. 2020

Journal of Computational Physics

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Numerical Cherenkov radiation (NCR) or instability is a detrimental effect frequently found in electromagnetic particle-in-cell (EM-PIC) simulations involving relativistic plasma beams. NCR is caused by spurious coupling between electromagnetic-field modes and multiple beam resonances. This coupling may result from the slow down of poorlyresolved waves due to numerical (grid) dispersion and from aliasing mechanisms. NCR has been studied in the past for finite-difference-based EM-PIC algorithms on regular (structured) meshes with rectangular elements. In this work, we extend the analysis of NCR to finite-element-based EM-PIC algorithms implemented on unstructured meshes. The influence of different mesh element shapes and mesh layouts on NCR is studied. Analytic predictions are compared against results from finite-element-based EM-PIC simulations of relativistic plasma beams on various mesh types.

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Local, Explicit, and Charge-Conserving Electromagnetic Particle-In-Cell Algorithm on Unstructured Grids

Cited by 39 publications

References 66 publications

Finite element time-domain body-of-revolution Maxwell solver based on discrete exterior calculus

Finite element time-domain body-of-revolution Maxwell solver based on discrete exterior calculus

Electromagnetic Theory With Discrete Exterior Calculus

Diagnosing numerical Cherenkov instabilities in relativistic plasma simulations based on general meshes

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