Implementation of higher-order velocity mapping between marker particles and grid in the particle-in-cell code XGC

The global total- $f$ gyrokinetic particle-in-cell code XGC, used to study transport in magnetic fusion plasmas or to couple with a core gyrokinetic code while functioning as an edge gyrokinetic code, implements a five-dimensional continuum grid to perform the dissipative operations, such as plasma collisions, or to exchange the particle distribution function information with a core code. To transfer the distribution function between marker particles and a rectangular two-dimensional velocity-space grid, XGC employs a bilinear mapping. The conservation of particle density and momentum is accurate enough in this bilinear operation, but the error in the particle energy conservation can become undesirably large and cause non-negligible numerical heating in a steep edge pedestal. In the present work we update XGC to use a novel mapping technique, based on the calculation of a pseudo-inverse, to exactly preserve moments up to the order of the discretization space. We describe the details of the implementation and we demonstrate the reduced interpolation error for a tokamak test plasma using first- and second-order elements with the pseudo-inverse method and comparing with the bilinear mapping.

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On the accuracy of the binary-collision algorithm in particle-in-cell simulations of magnetically confined fusion plasmas

Journal of Plasma Physics ◽

10.1017/s0022377821000398 ◽

2021 ◽

Vol 87 (2) ◽

Author(s):

Timo P. Kiviniemi ◽

Eero Hirvijoki ◽

Antti J. Virtanen

Keyword(s):

Finite Difference ◽

Electric Fields ◽

Finite Size ◽

Binary Collision ◽

Conserved Quantities ◽

Fusion Plasmas ◽

Fusion Plasma ◽

Particle In Cell ◽

Magnetically Confined ◽

Scale Length

Ideally, binary-collision algorithms conserve kinetic momentum and energy. In practice, the finite size of collision cells and the finite difference in the particle locations affect the conservation properties. In the present work, we investigate numerically how the accuracy of these algorithms is affected when the size of collision cells is large compared with gradient scale length of the background plasma, a parameter essential in full- $f$ fusion plasma simulations. Additionally, we discuss implications for the conserved quantities in drift-kinetic formulations when fluctuating magnetic and electric fields are present: we suggest how the accuracy of the algorithms could potentially be improved with minor modifications.

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Simulation of Velocity Evolution of a Cold Collision-less Non-Magnetised Plasma by Particle-in-Cell Method

Frontiers in Advanced Materials Research ◽

10.34256/famr2023 ◽

2021 ◽

Vol 2 (2) ◽

pp. 18-25

Author(s):

Ananthanarasimhan J ◽

Anand M.S. ◽

Lakshminarayana R

Keyword(s):

Arc Discharge ◽

Particle Energy ◽

Field Energy ◽

Static System ◽

Plasma System ◽

Plasma Properties ◽

Particle In Cell ◽

Pic Method ◽

Background Ions ◽

Cold Collision

This work presents simple numerical simulation algorithm to analyse the velocity evolution of high density non-magnetized glow discharge (cold) collision-less plasma using Particle-in-Cell (PIC) method. In the place of millions of physical electrons and background ions, fewer particles called super particles are used for simulation to capture the plasma properties such as particle velocity, particle energy and electrical field of the plasma system. The plasma system which is of interest in this work is weakly coupled plasma having quasi-neutrality nature. Simulation results showed symmetric velocity distribution about zero with slight left skewness, indicating static system. The order of directional velocity of individual particle seems to agree with the input electron temperature of the considered plasma system. The particle and field energy evolution were observed having fluctuations about zero which indicates that the system is equilibrating. This work marks the preliminary work to study the transport of plasma species in plasma column of gliding arc discharge.

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Three-dimensional particle-in-cell with Monte Carlo collision simulation of the electron energy distribution function in the multi-cusp ion source for proton therapy

Chinese Physics C ◽

10.1088/1674-1137/36/10/018 ◽

2012 ◽

Vol 36 (10) ◽

pp. 1013-1018

Author(s):

Chao Yang ◽

Xiao-Bing Wu ◽

Da-Gang Liu

Keyword(s):

Monte Carlo ◽

Distribution Function ◽

Energy Distribution ◽

Electron Energy ◽

Proton Therapy ◽

Electron Energy Distribution Function ◽

Three Dimensional ◽

Ion Source ◽

Energy Distribution Function ◽

Particle In Cell

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A particle-in-cell Monte Carlo simulation of an rf discharge in methane: frequency and pressure features of the ion energy distribution function

Plasma Sources Science and Technology ◽

10.1088/0963-0252/15/3/015 ◽

2006 ◽

Vol 15 (3) ◽

pp. 402-409 ◽

Cited By ~ 10

Author(s):

O V Proshina ◽

T V Rakhimova ◽

A T Rakhimov

Keyword(s):

Monte Carlo Simulation ◽

Monte Carlo ◽

Distribution Function ◽

Energy Distribution ◽

Energy Distribution Function ◽

Rf Discharge ◽

Ion Energy ◽

Ion Energy Distribution ◽

Particle In Cell

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TeV Blazar Gamma‐Ray Emission Produced by a Cooling Pileup Particle Energy Distribution Function

The Astrophysical Journal ◽

10.1086/424905 ◽

2004 ◽

Vol 616 (1) ◽

pp. 136-146 ◽

Cited By ~ 34

Author(s):

Ludovic Sauge ◽

Gilles Henri

Keyword(s):

Distribution Function ◽

Energy Distribution ◽

Gamma Ray ◽

Particle Energy ◽

Energy Distribution Function ◽

Gamma Ray Emission

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Neutron Time-of-Flight Measurements of Charged-Particle Energy Loss in Inertial Confinement Fusion Plasmas

Physical Review Letters ◽

10.1103/physrevlett.123.165001 ◽

2019 ◽

Vol 123 (16) ◽

Cited By ~ 4

Author(s):

D. B. Sayre ◽

C. J. Cerjan ◽

S. M. Sepke ◽

D. O. Gericke ◽

J. A. Caggiano ◽

...

Keyword(s):

Charged Particle ◽

Energy Loss ◽

Inertial Confinement Fusion ◽

Particle Energy ◽

Inertial Confinement ◽

Fusion Plasmas ◽

Confinement Fusion ◽

Neutron Time ◽

Flight Measurements ◽

Particle Energy Loss

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Oberflächenspannung und Thermodynamik des perfekten Gases

Zeitschrift für Naturforschung A ◽

10.1515/zna-1970-8-904 ◽

1970 ◽

Vol 25 (8-9) ◽

pp. 1190-1202 ◽

Cited By ~ 3

Author(s):

Eberhard Hilf

Keyword(s):

Particle Density ◽

Level Density ◽

Thermodynamic System ◽

Particle Energy ◽

External Potential ◽

Additional Contribution ◽

Quantum Gas ◽

Surface Phenomena ◽

Perfect Gas ◽

Thermodynamic Variable

Abstract A thermodynamic system of N Fermions or Bosons, bound by an external potential but with almost no additional contribution of the interaction energy between the particles to the binding of the system is called a bound perfect quantum gas. Its single particle energy level density ρ (ε) depends on the properties of the external potential. This is chosen to be zero inside and infinite outside a given arbitrary simple connected closed shape. Within the leptodermous assumption A N1/3 ≫ 1 then ρ (ε) can be written explicitly as a sum of three terms which are proportional to the volume, surface, curvature tension. Its thermodynamics is developed: 1) one thermodynamic variable can be eliminated, reducing the phase space dimensions; 2) the Gibbs - Duhem relation is disfigured only by surface - and curvature terms, stating that the system is still makroscopically homogenious except in the surface area, where e.g. the particle density falls down to zero smoothly; 3) the Landsberg-definition p · V = ⅔ U still holds, confirming that our microscopically defined system is macroscopically a perfect gas in the sense of Landsberg, despite the surface phenomena. In the appendix the advantages of an operatorlike shortwriting of the partial derivative notation are demonstrated.

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