JINTRAC: A system of codes for integrated simulation of Tokamak scenarios
Artikel i vetenskaplig tidskrift, 2014

Operation and exploitation of present and future Tokamak reactors require advanced scenario modeling in order to optimize engineering parameters in the design phase as well as physics performance during the exploitation phase. The simulation of Tokamak scenarios involves simultaneous modeling of different regions of the reactor, characterized by different physics and symmetries, in order to predict quantities such as particle and energy confinement, fusion yield, power deposited on wall, wall load from fast particles. JINTRAC is a system of 25 interfaced Tokamak-physics codes for the integrated simulation of all phases of a Tokamak scenario. JINTRAC predictions reflect the physics and assumptions implemented in each module and extensive comparison with experimental data is needed to allow validation of the models and improvement of Tokamak-physics understanding. © 2014 The Japan Society of Plasma Science and Nuclear Fusion Research.

Scrape-off layer

Transport

Fuelling and heating

Integrated modelling

Scenario modelling

Tokamak

Författare

M. Romanelli

Culham Lab

G.C. Corrigan

Culham Lab

V.V. Parail

Culham Lab

S. Wiesen

Culham Lab

Forschungszentrum Jülich

R. Ambrosino

Universita degli Studi di Napoli Federico II

P.C. Da Silva Aresta Belo

Instituto Superior Tecnico

Culham Lab

L. Garzotti

Culham Lab

D.M. Harting

Culham Lab

F. Kochl

Culham Lab

Technische Universität Wien

T. Koskela

Aalto-Yliopisto

Culham Lab

L. Lauro Taroni

Culham Lab

C. Marchetto

Culham Lab

Consiglio Nazionale delle Ricerche

M. Mattei

Universita degli Studi di Napoli Federico II

E. Militello Asp

Culham Lab

M. F. Nave

Instituto Superior Tecnico

S.J.P. Pamela

Culham Lab

A. Salmi

Aalto-Yliopisto

Pär Strand

Chalmers, Rymd- och geovetenskap, Plasmafysik och fusionsenergi

G. Szepesi

Chalmers University of Technology

Plasma and Fusion Research

1880-6821 (ISSN)

Vol. 9

Ämneskategorier

Fusion, plasma och rymdfysik

DOI

10.1585/pfr.9.3403023