Modelling of Impurity Transport in the Linear Plasma Devices PISCES-B and Pilot-PSI Using the Monte-Carlo Code ERO

被引：18

作者：

Borodin, D. ^{[1
]}

Kirschner, A. ^{[1
]}

Nishijima, D. ^{[2
]}

Doerner, R. ^{[2
]}

Westerhout, J. ^{[3
]}

van Rooij, G. J. ^{[3
]}

Rapp, J. ^{[3
]}

Kreter, A. ^{[1
]}

Ding, R. ^{[1
]}

Galonska, A. ^{[1
]}

Philipps, V. ^{[1
]}

机构：

[1] Forschungszentrum Julich, Assoc EURATOM FZJ, Inst Energieforsch Plasmaphys, D-52425 Julich, Germany

[2] Univ Calif San Diego, La Jolla, CA 92093 USA

[3] EURATOM, FOM Inst Plasma Phys Rijnhuizen, Trilateral Euregio Cluster, Nieuwegein, Netherlands

来源：

CONTRIBUTIONS TO PLASMA PHYSICS | 2010年 / 50卷 / 3-5期

关键词：

Plasma impurities; beryllium; hydrocarbons; spectroscopy; plasma-surface interaction; CHEMICAL EROSION;

D O I：

10.1002/ctpp.201010069

中图分类号：

O35 [流体力学]; O53 [等离子体物理学];

学科分类号：

070204 ; 080103 ; 080704 ;

摘要：

The simulations for linear devices using the 3D Monte-Carlo code ERO have a number of particularities of both physical and technical nature. Many physical effects introduced and tested for these simulations (elastic collisions, population of metastable states, etc.) can be relevant for tokamaks as well. The current status of these activities is summarized. As an example some simulations reproducing the experimental observations at PISCES-B and Pilot-PSI are presented. Main deviations and ideas for their origins are discussed. (c) 2010 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

引用

页码：432 / 438

页数：7

共 6 条

[1] Modelling of Impurity Transport in the Linear Plasma Devices PISCES-B and Pilot-PSI Using the Monte-Carlo Code ERO (vol 50, pg 432, 2010)
Borodin, D.
CONTRIBUTIONS TO PLASMA PHYSICS, 2011, 51 (01) : 99 - 99
[2] Modelling of chemical erosion mitigation experiments at PISCES-B using the 3D Monte-Carlo code ERO
Borodin, D.
Kirschner, A.
Droste, S.
Doerner, R.
Nishijima, D.
Baldwin, M.
Pigarov, A.
Hollmann, E.
Antar, Gh
Serayderian, R.
Philipps, V.
Mertens, Ph
Samm, U.
PHYSICA SCRIPTA, 2007, T128 : 127 - 132
[3] Impurity transport modelling in edge plasmas of fusion devices with the Monte Carlo code ERO
Droste, S.
Borodin, D.
Virschner, A.
Kreter, A.
Philipps, V.
Samm, U.
CONTRIBUTIONS TO PLASMA PHYSICS, 2006, 46 (7-9) : 628 - 634
[4] Modeling of tungsten transport in the linear plasma device PSI-2 with the 3D Monte-Carlo code ERO
Marenkov, E.
Eksaeva, A.
Borodin, D.
Kirschner, A.
Laengner, M.
Kurnaev, V.
Kreter, A.
Coenen, J. W.
Rasinski, M.
JOURNAL OF NUCLEAR MATERIALS, 2015, 463 : 268 - 271
[5] Modelling of Impurity Transport and Plasma-Wall Interaction in Fusion Devices with the ERO Code: Basics of the Code and Examples of Application
Kirschner, A.
Tskhakaya, D.
Kawamura, G.
Borodin, D.
Brezinsek, S.
Ding, R.
Linsmeier, Ch.
Romazanov, J.
CONTRIBUTIONS TO PLASMA PHYSICS, 2016, 56 (6-8) : 622 - 627
[6] Liquid metals as a divertor plasma-facing material explored using the Pilot-PSI and Magnum-PSI linear devices
Morgan, T. W.
Rindt, P.
van Eden, G. G.
Kvon, V.
Jaworksi, M. A.
Cardozo, N. J. Lopes
PLASMA PHYSICS AND CONTROLLED FUSION, 2018, 60 (01)

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